Get documents about "Parameter Reference for Huawei BSC6900
Description
This guide describes the meaning and effect of all the parameters of the Huawei BSC6900 and also details how to effectively fine tune the GSM network
Document Sample
BSC6900 GSM V900R011C00
Parameter Reference
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Purpose
This document provides information about the BSC6900 parameters, including the meaning, value, and usage of th
Intended Audience
•Network planners
•Field engineers
•System engineers
•Shift operators
Organization
Each parameter is described in the following aspects.
Description
Parameter ID
Parameter Name
NE
MML Command
Meaning
Feature ID
Feature Name
Value Type
GUI Value Range
Actual Value Range
Unit
Default Value
Recommended Value
Impact
Parameter Relationship
Access
Service Interrupted After Modification
Interruption Scope
Interruption Duration (min)
Caution
Validation of Modification
Impact on Radio Network Performance
Introduced in Version
Attribute
about the BSC6900 parameters, including the meaning, value, and usage of the parameters.
ollowing aspects.
Remarks
Simple string for identifying a parameter
Full name of the parameter
NEs on which the parameter is set
Commands for setting the parameter, and optional/mandatory attribute of the
parameter in each command
Functions, functioning ways, and protocols of the parameter
Relevant feature ID
Features using the parameter
Parameter value type
Parameter value range displayed on the GUI
Actual parameter value range corresponding to the GUI Value Range. For example,
the GUI Value Range is 0, and the corresponding Actual Value Range is OFF.
Parameter value unit
Initial value provided by the system
Values recommended in different scenarios
Parameter impact scope, that is, objects specified when the parameter is set
Relationship between this parameter and other parameters. For example, to use this
parameter, you need to set related switches and parameters.
Whether this parameter is read/write or read only
Whether modifying the parameter value may interrupt the existing services
Possible interruption scope in the case that modifying the parameter value may
interrupt the existing services
Possible interruption duration in the case that modifying the parameter value may
interrupt the existing services
Cautions to be taken during the modification
Requirements on how to validate the modification of the parameter. For example, you
may need to reset the device to validate the modification.
Impact of the radio parameter on the network performance
Version in which this parameter is introduced
Whether this parameter is a radio parameter, a transport parameter, or an equipment
parameter
Parameter ID Parameter Name
ABCDownQuality Downlink Quality Threshold in Assigning Better Cell
ABCUpQuality Uplink Quality Threshold in Assigning Better Cell
ABCWaitMaxTime Maximum Better Cell Assigning Duration
ABISBYPASSMODE Abis ByPass Mode
ABISFCEN SDCCH Congestion Flow Control Allowed
AbisFCTimer1 Abis Flow Control Timer 1
AbisFCTimer2 Abis Flow Control Timer 2
ABISIDLETSALLOC Abis Idle TS Allocate Strategy
ABISIDLETSCFGSWITCH Abis Idle TS Configure Switch
AbisJamThreshold2StartLs Abis Jam Rate for BTS Local Switch
ABISRESADJTCHHFUNSW TCHH Function Switch
ABISTSFREETM Timer of Releasing Abis Timeslot
AbisVer Abis Interface Tag
ABLASTTIME Duration of BTS Collecting AB[100 Millisecond]
AbnormalMosThreshold Abnormal Voice MOS Threshold
ACCBURST Access Burst Type
ACCCONTROLCLASS Access Control Class
ACCCTRLEN Access Control Allowed
ACCCTRLPY Access Control Policy
ACCESSOPTILAY Incoming-to-BSC HO Optimum Layer
ACCINDEX Access Control Policy Index
AccStaServiceType PS Initial Access Service Type
ACCWPOS Starting Point of the Access Control Window
ACCWSIZE Access Control Window Size
ACCWSP Sliding Speed of the Access Control Window
ACFC Address and control field compress
ACFC Support Address and Control Field Compress
ACOOPERATPAGINGSWITCH A Interface Paging Co-ordination Switch
ACS Additional Reselect Parameter Indication
ACTCDSETF AMR ACS[F]
ACTCDSETH AMR ACS[H]
ACTCDSETWB AMR ACS[WB]
ACTL2REEST Activate L2 Re-establishment
ACTTIME Valid Time of BTS Resource Activation
ACVLTHD AC Voltage Lower Threshold
ACVOLALARMH AC Overvoltage Alarm Threshold
ACVOLALARML AC Undervoltage Alarm Threshold
ACVUTHD AC Voltage Upper Threshold
ADAPTASSIGNMENTFLOW Assignment Procedure in Intra-Cell HO Allowed
ADDR Communication Address
Sub-Link Bandwidth Request Interval When Not
AddTransBwInt Congested
AddTransBwNum Bandwidth for Secondary Link When Not Congested
ADEF External Alarm Customer Definition Switch
ADJBSCDPC Adjacent BSC DPC
ADJMODE Adjustment Mode
ADJUSTULMCSTYPE Support EGPRS Uplink MCS Dynamic Adjust
ADLDACT Auto Download Active Function Switch
ADMODE Auto Download Mode
ADMSTAT Administrative State
ADMSTAT Administrative State
ADMSTAT Administrative State
ADTET Offset Time Adjustment End Time
ADTLOD Load Threshold of Offset Adjustment
ADTON Offset Time Adjustment Switch
ADTST Offset Time Adjustment Start Time
ADVALMMGRULETP Advanced Alarm Management Rule Type
ADVER1 BTS Software Version 1
ADVER2 BTS Software Version 2
AEC_Echo_Path_Delay AEC Echo Path Delay
AEC_Echo_Return_Loss AEC Echo Return Loss
AEC_Nlp_Gate AEC Nlp Gate
AEC_Path_Delay AEC Path Delay
AEC_SNR_Gate AEC SNR Gate
AEC_Switch AEC Switch
AECDetectThreshold AEC Detect Threshold
AECDetectTime AEC Detect Time
AFRDSBLCNT AFR Radio Link Timeout
AFRSAMULFRM AFR SACCH Multi-Frames
AGPSRECEIVERID GPS ID
AGPSRECEIVERTYPE GPS type
AHRDSBLCNT AHR Radio Link Timeout
AHRSAMULFRM AHR SACCH Multi-Frames
AID Alarm ID
AID Alarm ID
AID Alarm ID
AID Alarm ID
AID Alarm ID
AID Alarm ID.
AID Alarm ID.
AIDDELAYPROTECTTIME Aiding Delay Protect Time
AIDST Alarm Select Type
AIDST Alarm Select Type
AInterMsgTrace A Interface Msg [End2end User Tracing]
AINTFFCDISCLUEN A IF FC Discard LOC UP Enable
AINTFFCDISCMOCEN A IF FC Discard MOC Enable
AINTFFCDISCMTCEN A IF FC Discard MTC Enable
AINTFFCDISCOSEN A IF FC Discard Other Service Enable
AINTFFCEN A Interface Flow Control Enable
AINTFFCMETHOD A Interface Flow Control Method
AINTFFCRSRATE1 A IF FC Service Rate in Level 1
AINTFFCRSRATE2 A IF FC Service Rate in Level 2
AINTFFCRSRATE3 A IF FC Service Rate in Level 3
AINTFFCRSRATE4 A IF FC Service Rate in Level 4
AINTFFCRSRATE5 A IF FC Service Rate in Level 5
AINTFFCRSRATE6 A IF FC Service Rate in Level 6
AIPCSDSRVRDNDLEV CSD Service Redundancy Level
ALC_Fix_Gain ALC Fix Gain
ALC_Fix_Target_Level ALC Fix Target Level
ALC_Max_Gain ALC Max Gain
ALC_Max_Target_Level ALC Max Target Level
ALC_Min_Target_Level ALC Min Target Level
ALC_Mode ALC Mode
ALC_Switch ALC Switch
ALIVERETRY Alive Retry
ALIVETIMER Alive Timer
AllBw Bandwidth
ALLOCDIFFTRX Resource Reallocation to Different Trx
ALLOCSINGLEPDCHFORSIGNALLING Allocate One PDCH for Signaling Data
ALLOWAMRHALFRATEUSERPERC Ratio of AMR-HR
ALLOWEDADAMULTIPLEX Allow EDA Multiplex
ALLOWEDMEASRPTMISSEDNUM Allowed Measure Report Missed Number
ALLOWHALFRATEUSERPERC Ratio of TCHH
ALLTSTYPE Timeslot Type
ALLTSTYPE Timeslot Type
ALMD0 Feed Tri. 0 TMA Low Current Alarm Threhold
ALMD1 Feed Tri. 1 TMA Low Current Alarm Threhold
ALMD2 Feed Tri. 2 TMA Low Current Alarm Threhold
ALMD3 Feed Tri. 3 TMA Low Current Alarm Threhold
ALMD4 Feed Tri. 4 TMA Low Current Alarm Threhold
ALMD5 Feed Tri. 5 TMA Low Current Alarm Threhold
ALMDISACDUR Alarm Disappear Accumulate Duration
ALMENABLE Alarm Enable Flag
AlmId Alarm ID.
ALMID Alarm ID.
ALMLMTDOWN Lower Alarm
ALMLMTUP1 Upper Alarm
ALMLMTUP2 Upper Alarm
ALMOCACDUR Alarm Occurrence Accumulate Duration
AlmOccurAccuTimeHThd Alarm Occur Accumulative Time Threshold
AlmOccurAccuTimeLThd Alarm Clear Accumulative Time Threshold
AlmOccurTimesHThd Alarm Occur Times Threshold
AlmOccurTimesLThd Alarm Clear Times Threshold
ALMPARACFGFLAG Alarm Parameter Configuration Enabled
ALMTP Alarm Type
ALPHA ALPHA
ALTIDECI Antenna Altitude Decimal Part
ALTITUDE GPS antenna altitude
ALTITUDE Antenna Altitude Int Part
ALTITUDEIMP GPS antenna altitude
ALVL Alarm Severity
ALVL Alarm Severity
AMPC0 Feed Tri. 0 TMA Configuration
AMPC1 Feed Tri. 1 TMA Configuration
AMPC2 Feed Tri. 2 TMA Configuration
AMPC3 Feed Tri. 3 TMA Configuration
AMPC4 Feed Tri. 4 TMA Configuration
AMPC5 Feed Tri. 5 TMA Configuration
AMRBTSPWRNUM AMR BTS PC Class
AMRCALLPCALLOWED Allow III Power Control For AMR
AMRDADTHAW AMR Downlink Adaptive Threshold Allowed
AMRDLLEVFTLEN AMR Filter Length for DL RX_LEV
AMRDLPREDLEND AMR DL MR. Number Predicted
AMRDLQHTHRED AMR DL Qual. Upper Threshold
AMRDLQLTHRED AMR DL Qual. Lower Threshold
AMRDLQUAFTLEN AMR Filter Length for DL Qual.
AMRDLQUALBADTRIG AMR DL Qual Bad Trig Threshold
AMRDLQUALBADUPLEV AMR DL Qual Bad UpLEVDiff
AMRDLSSHTHRED AMR DL RX_LEV Upper Threshold
AMRDLSSLTHRED AMR DL RX_LEV Lower Threshold
AMRFULLTOHALFHOALLOW AMR F-H Ho Allowed
AMRFULLTOHALFHOATCBADJSTEP AMR F-H Ho ATCB Adjust Step
AMRFULLTOHALFHOATCBTHRESH AMR F-H Ho ATCB Threshold
AMRFULLTOHALFHOPATHADJSTEP AMR F-H Ho Pathloss Adjust Step
AMRFULLTOHALFHOPATHTHRESH AMR F-H Ho Pathloss Threshold
AMRFULLTOHALFHOQUALTHRESH AMR F-H Ho Qual. Threshold
AMRFULLTOHALFHOTHRESH AMR F-H Traffic Threshold
AMRHALFTOFULLHOATCBTHRESH AMR H-F Ho ATCB Threshold
AMRHALFTOFULLHOPATHTHRESH AMR H-F Ho Pathloss Threshold
AMRHALFTOFULLHOQUALALLOW Allow AMR H-F Quality-based HO
AMRHALFTOFULLHOQUALTHRESH AMR H-F Ho Qual. Threshold
AMRHALFTOFULLHOTHRESH AMR H-F Traffic Threshold
AMRMAXADJPCVAL AMR MAX Up Adj. PC Value by Qual.
AMRMAXSTEP0 AMR MAX Down Adj. Value Qual. Zone 0
AMRMAXSTEP1 AMR MAX Down Adj. Value Qual. Zone 1
AMRMAXSTEP2 AMR MAX Down Adj. Value Qual. Zone 2
AMRMAXVALADJRX AMR MAX Up Adj. PC Value by RX_LEV
AMRMRCOMPREG AMR MR. Compensation Allowed
AMRPCADJPERIOD AMR PC Interval
AMRQUALSTEP AMR MAX Down Adj. PC Value by Qual.
AMRSADLUPGRADE AMR SACCH Downlink Power Upgrade
AMRTCHHPRIORALLOW AMR TCH/H Prior Allowed
AMRTCHHPRIORLOAD AMR TCH/H Prior Cell Load Threshold
AMRUADTHAW AMR Uplink Adaptive Threshold Allowed
AMRULLEVFTLEN AMR Filter Length for UL RX_LEV
AMRULPREDLEND AMR UL MR. Number Predicted
AMRULQHTHRED AMR UL Qual. Upper Threshold
AMRULQLOWTHRED AMR UL Qual. Lower Threshold
AMRULQUAFTLEN AMR Filter Length for UL Qual
AMRULQUALBADTRIG AMR UL Qual. Bad Trig Threshold
AMRULQUALBADUPLEV AMR UL Qual. Bad UpLEVDiff
AMRULSSHTHRED AMR UL RX_LEV Upper Threshold
AMRULSSLTHRED AMR UL RX_LEV Lower Threshold
AN19 MAX Retrans Reset Circle Msg on A-I
AN4 MAX Reset Mesg Retransmission on A-I
ANC_Max_Gain ANC Max Gain
ANC_Switch ANC Switch
ANC_Target_SNR ANC Target SNR
ANGLE RET Antenna Tilt Angle
ANI Adjacent Node ID
ANI Adjacent node ID
ANM Alarm Name
ANR_Mode ANR Mode
ANR_Noise_Reduction_Level ANR Noise Reduction Level
ANR_Noise_Target_Level ANR Noise Target Level
ANR_Switch ANR Switch
ANTAANGLE Antenna Azimuth Angle
ANTENNALONG GPS Antenna Delay
ANTENNAPOWERSWITCH Antenna Power Supply Switch
ANTIERRFLAG E1T1 anti-error switch
AntiTheftAllow Burglar Alarm Auto Clear Permit
ANTNO Antenna No.
ANTPASSNO Antenna Pass No
ANTPASSNO Sub-Location Group Antenna Pass No.
AORB Down TRX1 A or B
APN A interface port No.
APP Application type
APPTYPE Application Type
AqmM AQM N Update Interval
AqmMaxTh AQM Maximum Threshold
AqmMinTh AQM Congestion Threshold
AqmNinit AQM Packet Discard Initial Interval
AqmNLowerBound AQM Packet Discard Interval Lower Threshold
AqmNUpBound AQM Packet Discard Interval Upper Threshold
AqmSwitch AQM Switch
AqmTarTh AQM Target Threshold
AreaCode Area Code
AREAFLAG Area flag
AREAFLAG Area flag
AREDISTHD Abnormal Release Threshold
ARELBASE Abnormal Release Statistic Base
ARELWTHD Abnormal Warn Threshold
ARPRETRY ARP packet resend times
ARPTIMEOUT ARP packet time-out[100ms]
ASN A interface slot No.
ASN A interface slot No.
ASRN A interface subrack No.
ASS Event Type
ASS Event Type
AssignBetterCellEn Assigning Better Cell Allowed
ASSLOADJUDGEEN Assignment Cell Load Judge Enable
ASSOLRXLEVOFFSET Assign to Overlayer RxLev Offset
ASSORXUCN Associated RXU Board CN
ASSORXUCN Associated RXU Board CN
ASSORXUSN Associated RXU Board SN
ASSORXUSN Associated RXU Board SN
ASSORXUSRN Associated RXU Board SRN
ASSORXUSRN Associated RXU Board SRN
ASSThres Absolute Signal Strength Threshold
ASSTIMER T3107
AT1 T1
AT13 T13 -s
AT17 T17 -s
AT18 T18 -s
AT19 T19
AT20 T20
AT4 T4 -s
ATCBHOEN Concentric Circles ATCB HO Allowed
ATCBHYST Distance Hysteresis Between Boundaries
ATCBTHRED Distance Between Boundaries of Subcells
Ater8KSw Switch of 8K on Ater
AterCongHRFlag HR Allocation Flag
AterCongstRatio Congestion Ratio on Ater Resource
ATERIDX Ater connection path index
AterJamThreshold2StartLs Ater Jam Rate for BSC Local Switch
ATERMASK Ater Mask
ATEROMLFLAG Whether or not for OML
ATEROMLINX Ater OML Index
ATERPIDX Ater Connection Path Index
ATERSLID Ater Signaling Channel ID
ATERTRANSMODE Ater Interface Transfer Mode
ATN Antenna Tributary No.
ATSMASK A interface timeslot mask
ATT Attach-detach Allowed
ATTENFACTOR1 Antenna Tributary 1 Factor
ATTENFACTOR2 Antenna Tributary 2 Factor
AUSTOP Loop time[min]
AUSTOP Test time[min]
AUTHMODE Authentication Mode
AUTHMODE Validate mode
AUTHMODE Validate mode
AUTHMODE Validate Mode
AUTHNAME Validate user name
AUTHNAME Validate user name
AUTHNAME Validate User Name
AUTHPWD Validate password
AUTHPWD Validate password
AUTHPWD Validate Password
AUTHTYPE Validate protocol type
AUTHTYPE Validate protocol type
AUTHTYPE Validate Protocol Type
AUTO Auto negotiation
AUTOADDSRCON Add inter-subrack path automatically
AUTOADJULTHHYSTF Auto Adjust UL TH and Hysteresis [F]
AUTOADJULTHHYSTH Auto Adjust UL TH and Hysteresis [H]
AutoGetBtsLogFlag Support Auto Obtaining of BTS Logs
AUTONEG Automatic Negotiation Mode
AUTOTYPE Work Mode for Auto Download Activation
AUTOULKSW Auto Unlock Switch
AutoUnlockTime Auto Unlock Time
AUTYPE Administration unit type
AVer A Interface Tag
AVOL Alarm level
AVOL Alarm VOL.
B1B2SDTHRD B1B2 signal degraded threshold
B1B2SFTHRD B1B2 signal fail threshold
B3SDTHRD B3 signal degrade threshold
B3SFTHRD B3 signal fail threshold
BACK8KCLKSW1 Switch of backplane LINE1
BACK8KCLKSW2 Switch of backplane LINE2
BackupPath Backup Path
BACKUPPATH Path of Backup File
BADQUALDISCTHRES Bad Quality Disconnection Threshold
bAdvEstDlTbf Support Advance Downlink TBF Establishment
BAKDEVTAB BTS Interface Board Bar Code 2
BAKIP Backup port IP address
BAKMASK Backup port mask
BAKPWRSAVMETHOD Backup Power Saving Method
BAKPWRSAVPOLICY Backup Power Saving Policy
BANDINDICATOR1900 High Band Indicator of Cell 1900
BANDINDICATOR850 High Band Indicator of Cell 850
BANDINDICATOR900 High Band Indicator of Cell 900
BANTIME Forbidden time after MAX Times
BARCODLST Cabinet Bar Code List
BASEBTSID Reference BTS Index
BASETEMPERATURE Temperature Basis for Compensation
BASETEMPERATURE Temperature Basis for Compensation
BATTCAPACITY Battery Capacity
BATTENABLEDIN Battery Configuration Enabled
BATTERYDISCHARGEDEPTH Battery Discharge Depth
BATTTYPE Battery Type
BBAPSRVPN BBAP service listening port No.
BBDIF Up Down Balance Basic Difference
BC Battery Capcity
BCC BCC
BCC BCC
BCC BCC
BCCH BCCH FD
BCCHFREQ Main BCCH Frequency
BCCHTRXHP Frequency Hopping Mode of BCCH TRX
BCCONGESTALMBOUND BC Congestion Alarm Threshold
BCCONGESTRESALMBOUND BC Congestion Restore Alarm Threshold
BCDSCP DSCP of BG[QoS]
BCID BC Identifier
BCLC Battery Current Limiting Coefficient
BCV Boost-Charging Voltage
BE Battery Configuration Enabled
BEARP1PRIWEIGHT BestEffort-ARP1 Priority Weight
BEARP2PRIWEIGHT BestEffort-ARP2 Priority Weight
BEARP3PRIWEIGHT BestEffort-ARP3 Priority Weight
BEARTYPE DSP bear type
BEATSENDINGDIS Interval for Sending Heartbeat
BEPPERIOD Bep Period
BESTTDDCELLNUM Best TDD Cell Number
BET3GHOEN Better 3G Cell HO Allowed
BETTERCELLHOEN Better Cell Handover Enable
BETTERCELLLASTTIME Better Cell HO Valid Time
BETTERCELLSTATTIME Better Cell HO Watch Time
BFDDETECTCOUNT Detect multiplier of BFD packet
BFDSN BFD Session No.
BFRANGE Up Down Balance Floating Range
BHPREPOLICY Switchback Policy of Baseband FH Mutual Aid
BITOFFSET In Frame Bit Offset [1/8 bit]
BKGARP1PRIWEIGHT Background-ARP1 Priority Weight
BKGARP2PRIWEIGHT Background-ARP2 Priority Weight
BKGARP3PRIWEIGHT Background-ARP3 Priority Weight
BLKFILTERSW Alarm switch of blinking filter
BLKPRD Alarm blink threshold
BLKSTATPRD Observing time window of statistical alarm
BLKSTATSW Switch of statistics blinking alarm
BLOCKRETRY Block Retry
BLOCKTIMER Block Timer
BMPN BM Port No
BMSN BM Slot No
BMSRN BM Subrack No
BMTCFCTimerLen Timer Length of BM-TC Flow Control
BORROWDEVIP Borrow DevIP
BOXFLG To Alarm Box Flag
BP1 Position of Break Point 1
BP2 Position of Break Point 2
BQHOEN BQ HO Allowed
BQLASTTIME BQ HO Valid Time
BQMARGIN BQ HO Margin
BQSTATTIME BQ HO Watch Time
BRDCLASS Board Class
BRDCLASS Board Class
BRDCLASS Board Class
BRDCLASS Board Class
BRDNO Board No.
BRDNO Board No.
BRDRXBW Receive Bandwidth
BRDSWTYPE BTS Board Software Type
BRDTXBW Forward Bandwidth
BRDTYPE Board Type
BRDTYPE Board Type
BRDTYPE Board type.
BRDTYPE Board type
BRDTYPE Board type
BRDTYPE Board type
BrdType Board Type
BRDTYPE Board Type
BREAKTIME Ring II Wait Time Before Switch
BROADCASTCONTENT Broadcast Content
BROADCASTINTERVAL Broadcast Interval
BS Backup Style
BSAGBLKSRES CCCH Blocks Reserved for AGCH
BSCDPC External BSC DPC
BSCDynSwitchTrxPAAllow Allow Dynamic Shutdown of TRX by BSC
BSCFLAG BSC Flag
BSCGATEWAYIP BSC GateWay IP
BSCGATHET BSC Offset Information Collection End Time
BSCGATHST BSC Offset Information Collection Start Time
BSCID BSC ID
BSCIDX BSC Index
BSCINCHPRD BSC Fine Tuning Period
BSCIP BSC IP
BSCIP BSC IP
BscLsStartMode Options for BSC Local Switch
BSCNAME External BSC Name
BSCPMA Preemption Allowed
BSCPMAIRAHO Preemption Allowed During Intra-BSC Handover
BSCPN In-BSC Port No.
BSCPORT BSC Port
BSCPRICLASS eMLPP Multi-Priority Classes Allowed
BSCQAD Queue Allowed
BSCQADIRAHO Queuing Allowed During Intra-BSC Handover
BSCRESERVEDPARA1 Reserved parameter 1
BSCRESERVEDPARA10 Reserved parameter 10
BSCRESERVEDPARA11 Reserved parameter 11
BSCRESERVEDPARA12 Reserved parameter 12
BSCRESERVEDPARA13 Reserved parameter 13
BSCRESERVEDPARA14 Reserved parameter 14
BSCRESERVEDPARA15 Reserved parameter 15
BSCRESERVEDPARA16 Reserved parameter 16
BSCRESERVEDPARA17 Reserved parameter 17
BSCRESERVEDPARA18 Reserved parameter 18
BSCRESERVEDPARA19 Reserved parameter 19
BSCRESERVEDPARA2 Reserved parameter 2
BSCRESERVEDPARA20 Reserved parameter 20
BSCRESERVEDPARA21 Reserved parameter 21
BSCRESERVEDPARA22 Reserved parameter 22
BSCRESERVEDPARA23 Reserved parameter 23
BSCRESERVEDPARA24 Reserved parameter 24
BSCRESERVEDPARA25 Reserved parameter 25
BSCRESERVEDPARA26 Reserved parameter 26
BSCRESERVEDPARA27 Reserved parameter 27
BSCRESERVEDPARA28 Reserved parameter 28
BSCRESERVEDPARA29 Reserved parameter 29
BSCRESERVEDPARA3 Reserved parameter 3
BSCRESERVEDPARA4 Reserved parameter 4
BSCRESERVEDPARA5 Reserved parameter 5
BSCRESERVEDPARA6 Reserved parameter 6
BSCRESERVEDPARA7 Reserved parameter 7
BSCRESERVEDPARA8 Reserved parameter 8
BSCRESERVEDPARA9 Reserved parameter 9
BSCSN In-BSC Slot No.
BSCSRN In-BSC Subrack No.
BSCSUBTS In-BSC Sub Timeslot No.
BSCSYMOFF BSC Symbol Offset
BSCTID ID of BSC in TC Pool
BSCTID ID of a BSC in TC Pool
BSCTS In-BSC Timeslot No.
BSCVMAX BS_CV_MAX
BSMSPWRLEV Transfer BTS/MS Power Class
BSPAGBLKSRES Number of PAGCH Blocks
BSPAMFRAMS Multi-Frames in a Cycle on the Paging CH
BSPBCCHBLKS Number of PBCCH Blocks
BSPRACHBLKS Number of PRACH Blocks
BssLsGenMode BSS Local Switching General Strategy
BSSLSMSCCOOP MSC-Collaborated BSS Local Switching
BSSPAGINGCOORDINATION BSS Paging Co-ordination
BT Board type
BT Board type
BT Board type
BT Board type
BT Board type
BT Board type
BT Board type
BT Board Type
BT Board Type
BT Board type
BT Board Type
BT Board Type
BT Board Type
BT Board Type
BT Board Type
BT Board Type
BTCFLAG BM/TC config flag
BTCFLAG BM/TC config flag
BTSadjust Adjust Voltage
BTSBARCODE BTS Bar Code
BTSCOMTYPE BTS Communication Type
BTSCOMTYPE BTS Communication Type
BTSDESC BTS Description
BTSDETECTSWITCH BTS Detect Switch
BTSID Site Index
BTSID BTS Index
BTSID BTS Index
BTSIDCONBSC Connect BSC BTS Index
BTSIDLST BTS Index List
BTSIDTYPE BTS Index Type
BTSIDTYPE BTS Index Type
BTSIDX Site Index Collect
BTSIP BTS IP
BtsLsStartMode Options for BTS Local Switch
BTSMASK Subnet Mask
BTSMESRPTPREPROC MR.Preprocessing
BTSNAME BTS Name
BTSNAMECONBSC Connect BSC BTS Name
BTSNAMELST BTS Name List
BTSPINGSWITCH BTS Ping Switch
BTSPOWEROFFLOCKBCCH BTS Power-off Lock BCCH
BTSPWRNUM BTS PC Class
BTSSAICPCADJSWITCH Switch for BTS Supporting SAIC PC Adjust
BTSSWVER BTS Software Version
BTSTRCMPRATE Transmission Compression Ratio
BTSTYPE BTS Type
BTSTYPE BTS Type
BTSTYPE BTS Type
BTSWTR Time for Waiting to Restore
BTTSTTYPE BT Test Type
BTYPE Battery Type
BUILDTIME Ring II Try Rotating Duration Time
BUNDLINGFLAG Bundling Flag
BVCI PTP BVC Identifier
BVCI PTPBVC Identifier
BVCTF BVC Flow Control Timer
BWADJ Auto adjust bandwidth switch
BWDCONGBW Backward congestion remain bandwidth
BWDCONGCLRBW Backward congestion clear remain bandwidth
BWDCONGCLRTH Backward congestion clear remain ratio
BWDCONGTH Backward congestion remain ratio
BWDOVLDCLRRSVBW Backward overload congestion clear remain bandwidth
BWDOVLDCLRTH Backward overload congestion clear remain ratio
BWDOVLDRSVBW Backward overload congestion remain bandwidth
BWDOVLDTH Backward overload congestion remain ratio
BWDRESVHOTH Backward handover reserved ratio
BWDRSVHOBW Backward handover reserved bandwidth
BWMAXRATIO Max bandwidth estimate ratio [%]
BWMODE Bandwidth Mode
BWRTPTH Load Control algorithm BandWidth THD[%]
BWTHD Up Down Balance Alarm Threshold
BYCELLTYPE Cell Index Type
GPRS Cell Reselect Hysteresis Applied to C31
C31HYST Criterion
C32QUAL Exceptional Rule for GPRS Reselect Offset
CABINETDESC Cabinet Description
CABLST Cabinet List
CABT Is remote cabinet
CALLRESTABDIS Call Reestablishment Forbidden
CALVAL Calibration Value
CANPC PWRC
CAPCOVEROPTSWITCH Capacity and Coverage Optimize Switch
CARDFREATTR Card Frequency Attribute
CARRYFLAG Carry Flag
CARRYT The bearing type of the logic port
CARRYT Carry port type
CBA Cell Bar Access
CBCINDEX CBC INDEX
CBCIP CBC IP
CBCITFPARA CBC ITF Para
CBCPORT CBC Port
CbNonMsgTimer Cb No Message Disconnection Timer
CBQ Cell Bar Qualify
CBS Consent burst size [Byte]
CbShakeHandTimer Cell Broadcast Handshake Timer
CBSIGNLEN Filter Length for SDCCH CV_BEP
CBTRAFFLEN Filter Length for TCH CV_BEP
CC CC
CCAEnableSta Certificate Chain File Enabled State
CCCHLOADINDPRD CCCH Load Indication Period
CCCHLOADTHRES CCCH Load Threshold
CCDSCP DSCP of CONV[QoS]
CCMINTERVAL CCM Send Prid
CDRTTRYFBDTHRES Cell Directed Retry Forbidden Threshold
CELL1800OFF 1800 Reporting Offset
CELL1800THRED 1800 Reporting Threshold
CELL2GBA1BCCH 2G NCELL BCCH
CELL2GBA1TAG 2GBA1 Input Tag
CELL2GBA2BCCH 2G NCELL BCCH
CELL2GBA2TAG 2GBA2 Input Tag
CELL8PSKPOWERLEVEL Cell 8PSK Power Attenuation Grade
CELL900OFF 900 Reporting Offset
CELL900THRED 900 Reporting Threshold
CELLBARACCESS2 Cell Access Bar Switch
CELLCOVERAGETYPE Cell Coverage Type
CELLEQUCHGVOL Even Charging Voltage
CELLEQUCHGVOL Even Charging Voltage
CELLFLOATCHGVOL Float Charging Voltage
CELLFLOATCHGVOL Float Charging Voltage
CELLID Cell Index
CELLID Cell Index
CELLID Cell Index
CELLID Cell Index
CELLID Cell Index
CELLID Cell Index
CELLIDLST Cell List
CELLIDTYPE Cell Index Type
CELLIDTYPE Cell Index Type
CELLIDTYPE Cell Index Type
CELLINEXTP Cell Inner/Extra Property
CELLLAYER Layer of the cell
CELLLIST Cell Index List
CellListOptionSend Cell List Send Flag in ASS CMP
CELLMAXSD Cell SDCCH Channel Maximum
CELLNAME Cell Name
CELLNAME Cell Name
CELLNAME Cell Name
CELLNAMELIST Cell Name List
CELLOPPWRGRP Cell Operator Power Group
CELLOVERCVGRXLEVDLTH Cell Over Coverage DL RxLev Threshold
CELLOVERCVGTALTH Cell Over Coverage TA Threshold
CELLPAGINGOVERLOADCOUNTER Cell Paging Overload Threshold
CELLPWROFFEN Battery Power-off Allowed State
CELLPWROFFVOL Battery Power-off Voltage
CELLRESELSTRATEGY 2G/3G Cell Reselection Strategy
CELLRXQUALWORSENRATIOTHRSH Cell Rx Quality Worsen Ratio Threshold
CELLSCENARIO Cell Scenario
CELLSELECTAFTERCALLREL Select 3G Cell After Call Release
CELLTEMP1ALARMH High Temp Alarm Assembled Battery1
CELLTEMP1ALARML Low Temp Alarm Assembled Battery1
CELLTEMP1THRESHOLDH Upper Assembled Battery 1 Temp
CELLTEMP1THRESHOLDL Lower Assembled Battery1 TEMP Measure
CELLTEMPCOMPENABLED Battery Temperature Compensated Configure Enabled
CELLWEAKCVGRXLEVDLTH Cell Weak Coverage DL RxLev Threshold
CELLWEAKCVGTALTH Cell Weak Coverage TA Threshold
CENDTHD Congestion End Threshold
CertChain Certificate Chain File Name
CFGFLAG Board Parameter Configuration Enabled
CFGFLAG Carry Flag
CFGMODE BTS Configuration Mode
CFGSW Configure switch
CFLAG Board Parameter Configuration Enabled
CFLAG Board Parameter Configuration Enabled
CFM Confirm Password
CG Command Group
CG Command Group
CGET Congestion End Threshold
CGET Congestion End Threshold
CGIRACSWITCH CGI and RAC Plan Switch
CGN Command Group Name
CGN Cabinet Group No.
CGST Congestion Start Threshold
CGST Congestion Start Threshold
CGST Congestion Start Threshold
CHAINNCELLTYPE Chain Neighbour Cell Type
CHAINTORING Combine Type
CHALLOCSTRATEGY Channel Allocate Strategy
CHANFAULTALMPDCHTH PDCH Available Threshold of Channel Failure
CHANFAULTALMSWITCH Monitoring Alarm Switch for Channel Failure
CHANFAULTALMTCHTH TCH Available Threshold of Channel Failure
CHANID Chan ID
CHANINTERMESALLOW Active CH Interf. Meas.Allowed
CHANNELRATECODE Channel Rate Type Decode Expand
CHANPDOUTTIME PDCH Out-of-Synchronization Period
CHECKCOUNT Ping Check Timeout Counts
CheckingBTSConnection Auto Check of BTS Connection Port
ChkModA ANT_A ALD Current Detection Mode
ChkModB ANT_B ALD Current Detection Mode
CHKN Check Index
CHKN Check Index
CHKOFFTIMES Check Times for Off
CHKONTIMES Check Times for On
CHKSUMRX Calculate checksum when receive message
CHKSUMTX Calculate checksum when send message
CHKSUMTYPE Checksum arithmetic
CHKTYPE Check type
CHLDURATH Duration<hour>
CHNNO Channel No.
CHNNO Channel No.
CHNO Channel No.
CHNTSTTYPE Channel Test Type
CHNTYPE Channel Type
ChosenChInAssCmp ChosenCh Send Flag in ASS CMP
ChosenChInHoPerform ChosenCh Send Flag in HO Perform
ChosenChInHoReqAck ChosenCh Send Flag in HO REQ ACK
ChosenEncrypAlgInCiphCmp ChosenEncrypAlg Send Flag in Cipher CMP
ChosenEncrypAlgInHoPerform ChosenEncrypAlg Send Flag in HO Perform
ChosenEncrypAloInAssCmp ChosenEncrypAlg Send Flag in ASS CMP
ChosenEncrypAloInHoReqAck ChosenEncrypAlg Send Flag in HO REQ ACK
CHPWRINSUFFALLOWED Channel Assign Allow for Insuff Power
CHRCOLLECTSWITCH PS CHR Collect Switch
CHREQCSMAXMSGNUMINPERIOD Max CS CHAN REQ Num in Period
CHREQPSAVGMSGNUMINPERIOD Average PS CHAN REQ Num
CHREQSTATPERIOD CHAN REQ Statistical Period
CHTYPE Channel Type
CI Cell CI
CI1 Cell CI
CIC CIC
CIC CIC
Number of Different Frames in CIC One-Way Mute
CicDMuteDifCnt Detection
CicDMutePeriod CIC Downlink One-Way Mute Detection Period
CicDMuteSwitch CIC Downlink One-Way Mute Detection Switch
CicDMuteThre CIC Downlink One-Way Mute Detection Threshold
CicDMuteTime CIC Downlink One-Way Mute Detection Duration
CicPoolInAssFail CIC Pool Send Flag in ASS Fail
CicPoolInHoFail CIC Pool Send Flag in HO Fail
CicPoolListInAssFail CIC Pool List Send Flag in ASS Fail
CicPoolListInHoFail CIC Pool List Send Flag in HO Fail
CicPoolSendFlagInAssCmp CIC Pool Send Flag in ASS CMP
CicPoolSendFlagInHoAck CIC Pool Send Flag in HO REQ ACK
CIR Bandwidth [64kbps]
CIRESTVALUE C/I Estimate Value
CIUSLOTNO Slot No.
CIUSUBRACKNO Subrack No.
CLASS11DTM Support Class11 DTM
CLASSMARKQUERY Classmark Enquiry With 3G Request
CLEARTHD Error clear threshold
CLKMOD Clock Mode
CLKPRTTYPE Clock Protocol Type
CLKTYPE Clock board type
ClkType Clock Type
ClrDelay Clear Command Delay Time
CLRFLG Alarm Cleared Flag
ClrInterval Clear Command Time Interval
CMD Command Name
CMD Command Name
CMDSEQ Command Sequence
CN Cabinet No.
CN Cabinet No.
CN Cabinet No.
CN Port Cabinet No.
CN Cabinet No.
CN Cabinet No.
CNFAULTDELAY CN Fault Delay
CNID MSC ID
CNID SGSN Node ID
CNNODEIDX CN Node Index
CNOPERATORINDEX Operator Index
CNSTATEPOLICYFORGROUP CN State Policy For Group
CNT Records to Return
CNT Cabinet Type
CNT Cabinet Type
CNTL Counts Limit
CNTRISTHRD Upper count threshold of raised fault
CNTSTLTHRD Lower count threshold of raised fault
COBSCMSCADJEN Co-BSC/MSC Adj
CODE Code
COLDSET Refrigeration Equipment
COLTYPE Collection Type
COMBINERLOSS Combiner Loss
COMMACC Common Access Control Class
Complicacy Password Complexity
COMPRS BTS Transfer Compression Rate
COMSC Co-MSC
CONBSCBTSIDTYPE Connect BSC BTS Index Type
CONGCLRTHD0 Recover threshold of queue 0 [ms]
CONGCLRTHD1 Recover threshold of queue 1 [ms]
CONGCLRTHD2 Recover threshold of queue 2 [ms]
CONGCLRTHD3 Recover threshold of queue 3 [ms]
CONGCLRTHD4 Recover threshold of queue 4 [ms]
CONGCLRTHD5 Recover threshold of queue 5 [ms]
CONGTHD0 Congestion threshold of queue 0 [ms]
CONGTHD1 Congestion threshold of queue 1 [ms]
CONGTHD2 Congestion threshold of queue 2 [ms]
CONGTHD3 Congestion threshold of queue 3 [ms]
CONGTHD4 Congestion threshold of queue 4 [ms]
CONGTHD5 Congestion threshold of queue 5 [ms]
CONHOEN Concentric Circles HO Allowed
CONNECTPORTNO Connect Port No.
CONNPWR Connect power monitoring board
CONNTYPE Connection Type
CONNTYPE Connection Type
CONTHOMININTV Min Interval for Consecutive HOs
CONTINTV Interval for Consecutive HO Jud.
CONTPING Continue ping or not
Count Send PKT Count
CPRIDURATS Duration Second
CPS Allow Dynamic Shutdown of TRX
CPUN CPU NO
CRC4CHK CRC4 Check Switch
CRH Cell Reselect Hysteresis Parameters
CRL Certificate Revocation List File Name
CRLEnableSta Certificate Revocation List File State
CRMSGRESENDINT Channel Release Resend Interval
CRMSGRESENDNUM Channel Release Resend Number
CRO Cell Reselect Offset
CROCALTMTHRD Cross Call Detect Time Threshold
CROSSIPFLAG Cross IP address available flag
CSADDTINFO CHR Supplementary Info Output Control
CSBQTHR Bad Speech Quality Rate Threshold
CSCHRMR CHR MR Output
CSCLTERMABNORM Abnormal Call End Output Control
CSDATADL GSM CS data service downlink factor
CSDATAPATH CS data path
CSDATAPRI CS data priority
CSDATAUL GSM CS data service uplink factor
CSDSP CS Data Service PRI
CSHOINFO CHR Handover Information Output
CSMRBFCLR Output MR Before Call Release
CSMRBFHO Output MR Before Handover
CSOUTMODE CHR Output Mode
CSOUTRANGE CHR Output Range
CSRCDSW CHR Function Switch
CSSIGINFO CHR Signaling Output
CSTARTTHD Congestion Start Threshold
CSTRAFTYPE Service Type of CHR Output
CSVOICEDL GSM CS voice service downlink factor
CSVOICEINFO CHR Speech Information
CSVOICEPATH CS voice path
CSVOICEPRI CS voice priority
CSVOICEUL GSM CS voice service uplink factor
CSVSP CS Voice Service PRI
Self-healing Switch for Ethernet Adapter Traffic
CSW Monitoring
CT1 Timer alignment ready
CT2 Timer not aligned
CT3 Timer aligned
CT4E Timer emergency proving
CT4N Timer normal proving
CT5 Timer sending SIB
CT6 Timer remote congestion
CT7 Timer excessive delay of acknowledgement
CT9 Timer interval of resending FISU
CTHD Critical threshold
CTHD Critical threshold
CTRBSCDPC Control BSC DPC
CTRLACKTYPE Control Acknowledge Type
CTRLFLAG Control Flag
CTRLPORTCN Control Port Cabinet No.
CTRLPORTNO Control Port No.
CTRLPORTSN Control Port Slot No.
CTRLPORTSRN Control Port Subrack No.
CTRLSLOT Slot No.
CTRLSN Control Plane Slot No.
CTRLSRN Control Plane Subrack No.
CTRLSW CM Control Enable Switch
CurChannelInHoRqd HO_RQD Current Channel
CVer C-Version No.
CYCLE Period of New File Generation[min]
DATAFILE Data file
DATAQUAFLTLEN Filter Length for TCH Qual
DATASTRFLTLEN Filter Length for TCH Level
DATATRAFFSET Data Service Allowed
DATE Date Limit
DATE Date
DateRangeIndex Prohib DynShutdown TRX DateRangeIdx
Day Day
DBD Dead Band
DBFREQBCCHIUO BCCH IUO of Double Frequency Cell
DBLFREQADJCID Same Group Cell Index
DBLFREQADJCNAME Same Group Cell Name
DBLFREQADJIDTYPE Same Group Cell Index Type
DCLACN DC Low Voltage Alarm Cabinet No.
DCLAPN DC Low Voltage Alarm Port No.
DCLASN DC Low Voltage Alarm Slot No.
DCLASRN DC Low Voltage Alarm Subrack No.
DCVLTHD DC Voltage Lower Threshold
DCVOLALARMH DC Overvoltage Alarm Threshold
DCVOLALARML DC Under Voltage Alarm Threshold
DCVUTHD DC Voltage Upper Threshold
DefaultDynPdchPreTranNum Number of Dynamic Channel Pre-Converted
DELAYSENDRFCHREL T3111
DENO Destination entity No.
DESC Description
DESTEALSET Anti-theft Equipment
DESTIP Destination IP address
DESTIP Destination IP address
DESTIP Destination IP address
DESTMEPID RMEP ID
DESTNODE Transport Link Type
DESTNODE Dest Node Type
DESTSN Peer Slot No.
DESTSRN Peer Subrack No.
DESTSSN Peer Subsystem No.
DESTTRXID Destination Main BCCH TRX ID
DETECTFRAMEPERIOD Period of Mute Detect Class2 TRAU Frame
DETECTMULT Detect Period
DETECTSWITCH Switch for Abis Timeslot Detection
DEVICENAME Device Name
DEVICENO Device No.
DEVIP Borrowed device IP address
DEVTYPE Device IP Address Type
DF DL UARFCN
DFCBSN DFCB Board SN
DFCBSRN DFCB Board SRN
DFDPC Default DPC
DFTPORTSWT The Type of FTP Server Command Port
DGPSPERIOD DGPS data report period[min]
DHCPRLYGATEWAYIP DHCP Relay Gateway IP Address
DHCPRLYID DHCP Relay ID
DIESELENGINESAVESWITCH Diesel Engine Save Switch
DIFFBANDSDCCHUSINGOPTIMIZE Different Band SDCCH Using Optimize
DINM Date in Month
DINW Date in Week
DIR Directory
DIR File Directory
DirectedRetryAssFailSendEnable Directed Retry AssFail Send Enable
DIRECTRYEN Directed Retry
DIRMAGANSITEFLAG Directly Magnifier BTS Flag
DisconnectHandoverProtectTimer Disconnect Handover Protect Timer
DIVERSITY Diversity
DIVERT16QAMDELAY Diversity Transmitter 16QAM Delay
DIVERT32QAMDELAY Diversity Transmitter 32QAM Delay
DIVERT8PSKDELAY Diversity Transmitter 8PSK Delay
DivSwitch Four Diversity Receiver
DLADJPRD PwrCtrlDLAdjPeriod
DLAFSREXQUALHIGHTHRED DLAFSRexQualHighThred
DLAFSREXQUALLOWTHRED DLAFSRexQualLowThred
DLAHSREXQUALHIGHTHRED DLAHSRexQualHighThred
DLAHSREXQUALLOWTHRED DLAHSRexQualLowThred
DLCI The Identifier of Data Link Connection
DLCOEFFICIENTTSRAPIDADJ Fast DL Priority Decision Threshold
DLDCSPT Support Downlink Dual-Carrier
DLEDGETHRES Edge HO DL RX_LEV Threshold
DLFILTADJFACTOR III DL Filter Adjust Factor
DLFSREXQUALHIGHTHRED DLFSRexQualHighThred
DLFSREXQUALLOWTHRED DLFSRexQualLowThred
DlGprsTbfExpandOp Downlink GPRS TBF Window Expansion Optimization
DLHSREXQUALHIGHTHRED DLHSRexQualHighThred
DLHSREXQUALLOWTHRED DLHSRexQualLowThred
DLHYSTF1 AMR DL Coding Rate adj.hyst1[F]
DLHYSTF2 AMR DL Coding Rate adj.hyst2[F]
DLHYSTF3 AMR DL Coding Rate adj.hyst3[F]
DLHYSTH1 AMR DL Coding Rate adj.hyst1[H]
DLHYSTH2 AMR DL Coding Rate adj.hyst2[H]
DLHYSTH3 AMR DL Coding Rate adj.hyst3[H]
DLHYSTWB1 AMR DL Coding Rate adj.hyst1[WB]
DLHYSTWB2 AMR DL Coding Rate adj.hyst2[WB]
DLINTERFLEVLIMIT Interf.of DL Level Threshold
DLINTERFQUALLIMIT Interf.of DL Qual.Threshold
DlLdrThrd2GCell 2G Cell DL Basic Congest Thred
DLLEVFILTLEN Filter Length for DL RX_LEV
DLLTFERLOWTH Downlink Long-term FER Lower Threshold
DLLTFERTGT Downlink Long-term FER Target
DLLTFERUPTH Downlink Long-term FER Upper Threshold
DLLTTHADJFA Downlink Threshold Adjust Factor
DLMAXDOWNSTEP DLMAXDownStep
DLMAXUPSTEP DLMAXUpStep
DlOlcThrd2GCell 2G Cell DL Overload Congest Thred
DLPREDLEND DL MR. Number Predicted
DLQHIGHTHRED DL Qual. Upper Threshold
DLQLOWTHRED DL Qual. Lower Threshold
DLQUAFILTLEN Filter Length for DL Qual.
DLQUALBADTRIG DL Qual. Bad Trig Threshold
DLQUALBADUPLEV DL Qual. Bad UpLEVDiff
DLQUALIMIT DL Qual. Threshold
DLQUALIMITAMRFR DL Qual. Limit for AMR FR
DLQUALIMITAMRHR DL Qual. Limit for AMR HR
DLREXLEVADJFCTR DLRexLevAdjustFactor
DLREXLEVEXPFLTLEN DLRexLevExponentFilterLen
DLREXLEVHIGHTHRED DLRexLevHighThred
DLREXLEVLOWTHRED DLRexLevLowthred
DLREXLEVSLDWINDOW DLRexLevSlideWindow
DLREXQUALADJFCTR DLRexQualAdjustFactor
DLREXQUALEXPFLTLEN DLRexQualExponentFilterLen
DLREXQUALSLDWINDOW DLRexQualSlideWindow
DLRXLEVPROTECTFACTOR III DL RexLev Protect Factor
DLRXQUALPROTECTFACTOR III DL RexQual Protect Factor
DLSSHIGHTHRED DL RX_LEV Upper Threshold
DLSSLOWTHRED DL RX_LEV Lower Threshold
DLTBFESTDELAY Downlink TBF Establishment Delay
DLTESTRESENDINT Download Test Resend Interval
DLTESTRESENDNUM Download Test Resend Number
DLTHF1 AMR DL Coding Rate adj.th1[F]
DLTHF2 AMR DL Coding Rate adj.th2[F]
DLTHF3 AMR DL Coding Rate adj.th3[F]
DLTHH1 AMR DL Coding Rate adj.th1[H]
DLTHH2 AMR DL Coding Rate adj.th2[H]
DLTHH3 AMR DL Coding Rate adj.th3[H]
DLTHWB1 AMR DL Coding Rate adj.th1[WB]
DLTHWB2 AMR DL Coding Rate adj.th2[WB]
DMDUA Down MDU A
DMDUB Down MDU B
DN Domain
DNDEFAULTCS Downlink Default CS Type
DNDEFAULTMCS Downlink Default MCS Type
DNE2ADEFAULTMCS Downlink EGPRS2-A Default MCS Type
DNE2AFIXMCS Downlink EGPRS2-A Fixed MCS Type
DNFIXCS Downlink Fixed CS Type
DNFIXMCS Downlink Fixed MCS Type
DNPCEN DL PC Allowed
DNSENDSMDIS Short Message Downlink Disabled
DNTBFRELDELAY Release Delay of Downlink TBF
DNTHDCSDEGRADE1 Downlink TBF Threshold from CS2 to CS1
DNTHDCSDEGRADE2 Downlink TBF Threshold from CS3 to CS2
DNTHDCSDEGRADE3 Downlink TBF Threshold from CS4 to CS3
DNTHDCSUPGRADE1 Downlink TBF Threshold from CS1 to CS2
DNTHDCSUPGRADE2 Downlink TBF Threshold from CS2 to CS3
DNTHDCSUPGRADE3 Downlink TBF Threshold from CS3 to CS4
DOOR_ENGINE_MASK Enable Door Status Alarm Reporting
DOUBLEANTENNAGAIN Double Antenna Gain
DPC DSP code[Whole Number]
DPCDNF DSP code[Divided Number]
DPCGIDX DPC Group Index
DPCGIDX DPC Group Index
DPCGIDX DPC Group Index
DPCT DSP type
DPX DSP index
DPX DPX
DRHOLEVRANGE Directed Retry Handover Level Range
DROPCTRLABISCONNFAIL Drop Optimize ABIS Link Failure
DROPCTRLCONNFAILHOACCFAIL Drop Optimize Conn Fail[HO access fail]
DROPCTRLCONNFAILOM Drop Optimize Conn Fail[OM intervention]
DROPCTRLCONNFAILOTHER Drop Optimize Conn Fail[other]
DROPCTRLCONNFAILRLFAIL Drop Optimize Conn Fail[radio link fail]
DROPCTRLCONNFAILRRNOTAVL Drop Optimize Conn Fail[resource not available]
DROPCTRLEQUIPFAIL Drop Optimize Equipment Failure
DROPCTRLERRINDDMRSP Drop Optimize Err Ind[unsolicited DM response]
DROPCTRLERRINDSEQERR Drop Optimize Err Ind[sequence error]
DROPCTRLERRINDT200 Drop Optimize Err Ind[T200 timeout]
DROPCTRLFORCHOFAIL Drop Optimize Forced Handover Failure
DROPCTRLINBSCHO Drop Optimize Into-BSC Handover Timeout
DROPCTRLINTRABSCOUTHO Drop Optimize Intra-BSC Handover Timeout
DROPCTRLINTRACELLHO Drop Optimize Intra-Cell Handover Timeout
DROPCTRLNOMR Drop Optimize No MR for Long Time
DROPCTRLOUTBSCHOT8 Drop Optimize Out-BSC Handover Timeout
DROPCTRLRELIND Drop Optimize Release Indication
DROPCTRLRESCHK Drop Optimize Resource Check
DROPPKTTHD0 Packet discard threshold of queue 0 [ms]
DROPPKTTHD1 Packet discard threshold of queue 1 [ms]
DROPPKTTHD2 Packet discard threshold of queue 2 [ms]
DROPPKTTHD3 Packet discard threshold of queue 3 [ms]
DROPPKTTHD4 Packet discard threshold of queue 4 [ms]
DROPPKTTHD5 Packet discard threshold of queue 5 [ms]
DROPPWRINTERVAL Drop Power Time Interval[T3]
DROPPWRSTARTTIME Drop Power Start Time[T1]
DROPPWRSTEP Drop Power Step
DRXEN SMCBC DRX
DRXTIMERMAX Max. Duration of DRX
DRYSET Dehumidification Equipment
DS1 E1T1 port No.
DS1 E1T1 port No.
DSCP Differentiated Service Codepoint
DSCP Differentiated services code point
DSCP Differentiated Service Codepoint
DSCP DSCP
DSPKIFFOFFTIMER DSP Kickoff Timer
DSPN DSP No.
DSPN DSP No.
DSPN DSP No.
DSPN DSP No.
DSPNO DSP No.
DSPRECOVERTIMER DSP Recover Timer
DST DaylightSave
DSTF Destination File Name
DSTIP Destination IP address
DSTIP Destination IP Address
DSTIP Destination IP Address
DSTMASK Destination address mask
DSTMASK Destination Address Mask
DSTPORTNO Destination port No.
DSTTSMASK Destination timeslot mask
DTLOADTHRED Directed Retry Load Access Threshold
DTRTYPE DRX Type
DTRX Down Link No.
DTRX Down Link No.
DTRXPN Down TRX Board Pass No.
DTRXPN Down TRX Board Pass No.
DTRXSN Down TRX Slot No.
DTRXSN Down TRX Slot No.
DTRXSRN Down TRX Subrack No.
DTRXSRN Down TRX Subrack No.
DUMMYBITRANDSWITCH Dummy Bit Randomization Switch
DUPLEX Duplex Mode
DURATH Duration<Hour>
DURATH Duration Hour
DURATM Duration<minute>
DURATS Duration<s>
Downlink Multiplex Threshold of Dynamic Channel
DWNDYNCHNTRANLEV Conversion
DWNINTEN DL Signal Strength Limit
DXXINDEX Up DXX Index
DXXINDEX DXX Index
DXXPN Up DXX Port No.
DYNCHFREETM Timer of Releasing Idle Dynamic Channel
DYNCHNPREEMPTLEV Level of Preempting Dynamic Channel
Reservation Threshold of Dynamic Channel
DYNCHTRANRESLEV Conversion
DYNOpenTrxPower Allow Dynamic Shutdown of TRX
DYNPBTSUPPORTED Dynamic Transmission Div Supported
E1DURAT Duration
E1PORT Port No.
E1PORTNOINBTSCONBSC E1 Port No Connect To BSC
E1SLCTTMU Transmission Board Type
E1T1PN E1/T1 port No.
E1T1PN E1/T1 Port No.
E1T1PORTNO Backboard E1/T1 Port No.
E1T1TYPE E1/T1 Type
ECHOIP Check IP address
ECNOOFF Ec/No Offset
ECNOTHRES Ec/No Threshold for Layer Of 3G Cell
ECSC ECSC
ECSN End Serial No.
ED End Date
ED End Date
ED End Date
EDATE End Date
EDAY End date
EDBLASTTIME Number of Satisfactory Measurements
EDBSTATTIME Total Number of Measurements
EDBSYSFLOWLEV Subcell HO Allowed Flow Control Level
EDGE EDGE
EDGEADJLASTTIME Edge HO AdjCell Valid Time
EDGEADJSTATTIME Edge HO AdjCell Watch Time
EDGELAST Handover Algorithm II Edge HO Valid Time
EDGELAST1 Handover Algorithm I Edge HO Valid Time
EDGESTAT Handover Algorithm II Edge HO Watch Time
EDGESTAT1 Handover Algorithm I Edge HO Watch Time
EFTIMMFLAG Effect Immediately Flag
EGPRS11BITCHANREQ Support 11BIT EGPRS Access
EGPRS2A EGPRS2-A
EGPRSBEPLIMIT8PSK EDGE 8PSK Quality Threshold
EGPRSBEPLIMITGMSK EDGE GMSK Quality Threshold
EM EndType
EMCPRILV Priority of Emergency Call
EMERGENCY Emergency verification
EMITTHD Error emit threshold
EMLDSCP EML DSCP
EMLPPEN Allow EMLPP
EMLPPPRIORITY eMLPP Priority
EMLPPPRIORITY eMLPP Priority In Paging
EMLPRI EML Priority
EMLSP EML Service PRI
EMLVLANID EML VlanId
EMONTH End month
EMSIP EMS IP Address
ENABLE Fallback Function Enable
ENABLED TMA Power Supply Enabled
ENCRY Encryption Algorithm
ENCRYMODE Transport Encrypted Mode
ENCRYMODE The Encrypted Mode
End2EndTraceState Support End-to-end User Tracing Function
ENDAID End Alarm ID
ENDCIC End CIC
ENDCIC End CIC
EndDayDSTPA Prohibit Power Saving End Day
ENDHEATTEMP Heater Shutdown Temperature
EndMonthDSTPA Prohibit Power Saving End Month
ENDSUBTS End Sub Timeslot NO.
EndTimeTACloseTrxPA Time When the Function Is Disabled
ENDTS End TS
ENDTS End TS
ENDTS End Timeslot NO.
ENF Status
ENF Subtask Status
ENGOVERLDTHRSH En Iuo Out Cell General OverLoad Thred
ENGSMPSDLMACFLOWCTRL User Plane DL Flow Ctrl Switch
ENIUO Enhanced Concentric Allowed
ENLDHOPRD Load Classification HO Period
ENLDHOSTP Load Classification HO Step
ENLOWLDTHRSH En Iuo Out Cell Low Load Thred
ENPREEMPTTRANSADMT Transmission Resource Preempting Support
ENQUETRANSADMT Transmission Resource Queuing Support
ENSOVERLDTHRSH En Iuo Out Cell Serious OverLoad Thred
ENTCHADJALLOW Enhanced TCH Adjust Allowed
ENTITYT Local entity type
ENTITYT Destination entity type
ENUTOOLOADINILEV IniLev for EnUtoO Load HO
EPLCSwitch EPLC Switch
ERCODE Return Code
ERGCALLDIS Emergent Call Disable
ERRALARMTHD Error-frame alarm threshold
ERRDETECTSW Error-frame detect switch
ESLDSCP ESL DSCP
ESLPRI ESL Priority
ESLSP ESL Service PRI
ESLVLANID ESL VlanId
ESSN End Sync Serial No.
ESTABINDTIMER T3101
ESTINDL3MSGTAFLAG Add TA to A Interface EST IND
ESTTIME Ring II Rotating Penalty Time
ET EndTime
ET End Time
ET End Time
ET Execute Type
ET End Time
ET End Time
ET End Time
ET End Time
ETD End Date
ETIME End Time
ETP Log Type
ETT End Time
EWEEK End week
EWSEQ End week sequence
EX_ANO1_SIG_MAX Upper Limit of Signal Output of External Analog 1
EX_ANO1_SIG_MIN Lower Limit of Signal Output of External Analog 1
EX_ANO1_TYPE Sensor Type of External Analog 1
Upper Limit of Measurement Range of External Analog
EX_ANO1_VAL_MAX 1
Lower Limit of Measurement Range of External Analog
EX_ANO1_VAL_MIN 1
EX_ANO2_SIG_MAX Upper Limit of Signal Output of External Analog 2
EX_ANO2_SIG_MIN Lower Limit of Signal Output of External Analog 2
EX_ANO2_TYPE Sensor Type of External Analog 2
Upper Limit of Measurement Range of External Analog
EX_ANO2_VAL_MAX 2
Lower Limit of Measurement Range of External Analog
EX_ANO2_VAL_MIN 2
EX_ANO3_SIG_MAX Upper Limit of Signal Output of External Analog 3
EX_ANO3_SIG_MIN Lower Limit of Signal Output of External Analog 3
EX_ANO3_TYPE Sensor Type of External Analog 3
Upper Limit of Measurement Range of External Analog
EX_ANO3_VAL_MAX 3
Lower Limit of Measurement Range of External Analog
EX_ANO3_VAL_MIN 3
EX_ANO4_SIG_MAX Upper Limit of Signal Output of External Analog 4
EX_ANO4_SIG_MIN Lower Limit of Signal Output of External Analog 4
EX_ANO4_TYPE Sensor Type of External Analog 4
Upper Limit of Measurement Range of External Analog
EX_ANO4_VAL_MAX 4
Lower Limit of Measurement Range of External Analog
EX_ANO4_VAL_MIN 4
EXCACC Exclusive Access
EXCEPFRAMETHRES Exceptional Frame Threshold of Mute Detect Class1
EXPDLRXLEV Expected DL RX_LEV
EXPULRXLEV Expected UL RX_LEV
EXT2GCELLID Cell Index
EXT2GCELLNAME Cell Name
EXT3GCELLID Cell Index
EXT3GCELLNAME Cell Name
EXTADJCELLID BSC Adjacent Cell Index
EXTADJCELLNAME BSC Adjacent Cell Name
EXTCELLTHRENH Extended Cell Throughput Enhancement
EXTFlag Extended Switch of Input Alarm
EXTMEASORD Extension Measurement Command
EXTRPTPERIOD Extension MR Period
EXTRPTTYPE Extension MR Type
EXTTP Cell Extension Type
EXTUTBFNODATA Not Send Dummy Message with Extended Uplink TBF
FACCHRESENDINT FACCH Msg Resend Interval
FACCHSENDNOTMSGIND FACCH Send Notification Msg Indication
FACCHSENDPGMSGIND FACCH Send Paging Msg Indication
FACTORSW TRM Factor switch
FACTORYMODE Factory Mode
FAILSIGSTRPUNISH Penalty Level after HO Fail
FANADJUSTCOMMAND0 Continuous adjustment command
FANADJUSTCOMMAND1 Discrete adjustment command
FANADJUSTCOMMAND2 Duty ratio adjustment command
FANADJUSTMODE Fan adjustment mode
FANFLAG Fan Type
FANSPEEDMODE Speed adjustment mode
FANTYPE FanBox Type
FASTCALLTCHTHRESHOLD Fast Call Setup TCH Usage Threshold
FASTCNETFLAG Configure Ring II
FaultDetectSwitch Fault Detect Switch
FC Physical layer flow control switch
FC Flow Control
FCETHD Flow Control End Threshold
FCINDEX Flow control parameter index
FCINDEX Flow control parameter index
FCINDEX Flow control parameter index
FCINDEX Flow control parameter index
FCINDEX Flow control parameter index
FCINDEX Flow control parameter index
FCINDEX Flow control parameter index
FCN Cabinet No. of Parent BTS
FCN Cabinet No. of Father BTS
FCSTHD Flow Control Start Threshold
FCSTYPE CRC check mode
FCSTYPE CRC check mode
FCSW Flow control switch
FCV Float-Charging Voltage
FDDBA1TAG FDDBA1 Input Tag
FDDBA2TAG FDDBA2 Input Tag
FDDCELLOFF FDD Reporting Offset
FDDCELLTHRED FDD Reporting Threshold
FDDDIVERSITY Diversity Indication
FDDDLUARFAN Downlink Frequency
FDDECQUALTHRSH PS FDD Ec/No Quality Threshold
FDDFREQCNUM FDD Multirate Reporting
FDDQMIN FDD Qmin
FDDQMINOFFSET FDD Qmin Offset
FDDQOFF FDD Q Offset
FDDREP FDD REP QUANT
FDDRSCPMIN FDD RSCP Min.
FDDRSCPQUALTHRSH PS FDD RSCP Quality Threshold
FDDSCRAMBLE Scrambling Code
FDWINDOW Fast judgement window
FERRPTEN FER Report Enable
FERSTATTH1 FER Threshold 1
FERSTATTH2 FER Threshold 2
FERSTATTH3 FER Threshold 3
FERSTATTH4 FER Threshold 4
FERSTATTH5 FER Threshold 5
FERSTATTH6 FER Threshold 6
FERSTATTH7 FER Threshold 7
FHMODE Frequency Hopping Mode
FILE File Name
FILE Target File Path
FileName File Name
FILEPATH Export File Path
FILETYPE Log File Type
FILTERWNDSIZE Filter Window Size
FIN Final
FINESTEPPCALLOWED 0.2dB Power Control Enable
FIRESET Fire-extinguishing Equipment
FIXABISPRIORABISLOADTHRED Fix Abis Prior Choose Load Thred
FlashAlmClrThd Flash Alarm Clear Threshold
FlashAlmOccurThd Flash Alarm Occur Threshold
FlashFilterEn Flash Filter Enable
FlashStatisAlmClrTW Flash Statistic Alarm Clear Time Window
FlashStatisAlmOccurTW Flash Statistic Alarm Raise Time Window
FLEXABISMODE Flex Abis Mode
FLEXMAIO Start Flex MAIO Switch
FLEXTSCSWITCH Flex TSC Switch
FlowCountPeriodTicks Flux Measurement Period
FLOWCOUNTPERIODTSRAPIDADJ Fast Flux Measurement Period
FLOWCTRLSWITCH Flow control switch
FLOWCTRLSWITCH Flow control switch
FLOWCTRLSWITCH Flow control switch
FLOWCTRLSWITCH Flow control switch
FLOWCTRLSWITCH Flow control switch
FLOWCTRLSWITCH Flow control switch
FLTPARAA1 Filter Parameter A1
FLTPARAA2 Filter Parameter A2
FLTPARAA3 Filter Parameter A3
FLTPARAA4 Filter Parameter A4
FLTPARAA5 Filter Parameter A5
FLTPARAA6 Filter Parameter A6
FLTPARAA7 Filter Parameter A7
FLTPARAA8 Filter Parameter A8
FLTPARAB Filter Parameter B
FLUSHTRANSFERSWITCH FLUSH-LL PDU Transfer Switch
FMSMAXOPCC MS_TXPWR_MAX_CCH
FMUTYPE FMU Board Type
FN File Name
FN File Name
FN File Name
FN File Name
FN File Name
FN File Name
FN File Name
FORBIDEDGU Allow E Down G Up Switch
FORBIDNO7FLASHDISC Anti DPC Intermittent Disconnect Timer
Force_Limit_Time Force Limit Time
Force2Phase Force MS Two-phase Access
FORCEDCELLEFRSWITCH Allow Forced EFR in Cell
FORCEMSACCESS Force MS to Send Ho Access SWITCH
FPN Dest Father BTS Port No.
FPN Dest Father BTS Port No.
FPTIMER Maximum Delay Time[ms]
FQBSICOPTSWITCH Freq. and BSIC Optimize Switch
FQBSICSWITCH Freq. and BSIC Plan Switch
FQBSICSWITCH1 Freq. and BSIC Plan Switch
FRAGSIZE MP flake size
FRAMEOFFSET Frame Offset [Frame No]
FRAMEOFFSET Frame Offset
FRDLDTX FR Use Downlink DTX
FREQ Time Mode
FREQ Time Mode
FREQ Frequency
FREQ1 Frequency 1
FREQ10 Frequency 10
FREQ11 Frequency 11
FREQ12 Frequency 12
FREQ13 Frequency 13
FREQ14 Frequency 14
FREQ15 Frequency 15
FREQ16 Frequency 16
FREQ17 Frequency 17
FREQ18 Frequency 18
FREQ19 Frequency 19
FREQ2 Frequency 2
FREQ20 Frequency 20
FREQ21 Frequency 21
FREQ22 Frequency 22
FREQ23 Frequency 23
FREQ24 Frequency 24
FREQ25 Frequency 25
FREQ26 Frequency 26
FREQ27 Frequency 27
FREQ28 Frequency 28
FREQ29 Frequency 29
FREQ3 Frequency 3
FREQ30 Frequency 30
FREQ31 Frequency 31
FREQ32 Frequency 32
FREQ33 Frequency 33
FREQ34 Frequency 34
FREQ35 Frequency 35
FREQ36 Frequency 36
FREQ37 Frequency 37
FREQ38 Frequency 38
FREQ39 Frequency 39
FREQ4 Frequency 4
FREQ40 Frequency 40
FREQ41 Frequency 41
FREQ42 Frequency 42
FREQ43 Frequency 43
FREQ44 Frequency 44
FREQ45 Frequency 45
FREQ46 Frequency 46
FREQ47 Frequency 47
FREQ48 Frequency 48
FREQ49 Frequency 49
FREQ5 Frequency 5
FREQ50 Frequency 50
FREQ51 Frequency 51
FREQ52 Frequency 52
FREQ53 Frequency 53
FREQ54 Frequency 54
FREQ55 Frequency 55
FREQ56 Frequency 56
FREQ57 Frequency 57
FREQ58 Frequency 58
FREQ59 Frequency 59
FREQ6 Frequency 6
FREQ60 Frequency 60
FREQ61 Frequency 61
FREQ62 Frequency 62
FREQ63 Frequency 63
FREQ64 Frequency 64
FREQ7 Frequency 7
FREQ8 Frequency 8
FREQ9 Frequency 9
FREQADJ Frequency Adjust Switch
FREQADJVALUE Frequency Adjust Value
FREQBAND Frequency Band Attribute
FREQLOADSHARETRAFFTHRSH GSM900 Band Traffic Load Share Threshold
FREQLST Freq Band List
FREQREUSEMODE Frequency Reuse Mode
FREQS Frequency List
FREQSCANRLSTTYPE Frequency Scan Result Type
FRINGEHOEN Edge HO Allowed
FRULDTX FR Uplink DTX
FSN Slot No. of Father BTS
FSN Slot No. of Father BTS
FSRN Subrack No. of Parent BTS
FSRN Subrack No. of Father BTS
FT File Type
FTI Factor table index
FTI Factor table index
FTI Factor table index
FULLTOHALFHOATCBOFFSET F-H ATCB Offset Overlay
FULLTOHALFHODURATION F-H Ho Duration
FULLTOHALFHOLASTTIME F-H Ho Last Time
FULLTOHALFHOPATHOFFSET F-H Pathloss Offset Overlay
FULLTOHALFHOPERIOD F-H Ho Period
FULLTOHALFHOSTATTIME F-H Ho Stat. Time
FWDCONGBW Forward congestion remain bandwidth
FWDCONGCLRBW Forward congestion clear remain bandwidth
FWDCONGCLRTH Forward congestion clear remain ratio
FWDCONGTH Forward congestion remain ratio
FWDOVLDCLRRSVBW Forward overload congestion clear remain bandwidth
FWDOVLDCLRTH Forward overload congestion clear remain ratio
FWDOVLDRSVBW Forward overload congestion remain bandwidth
FWDOVLDTH Forward overload congestion remain ratio
FWDRESVHOTH Forward handover reserved ratio
FWDRSVHOBW Forward handover reserved bandwidth
G2G3GLdBlcDeltaThrd CS 2G 3G Load Balance Delta Threshold
G2GLoadAdjustCoeff 2G Load Adjustment Coefficient
G711_Mode G711 Mode
GAMMA GAMMA
GATHET Offset Information Collection End Time
GATHLOD Load Threshold of Offset Collection
GATHON Offset Information Collection Switch
GATHST Offset Information Collection Start Time
GBRQOS Support GBR QoS
GCChk Group Call Check
GCDF GCDF
GCSCHNASSULCHNEN VGCS Channel Assign in Channel Enable
GCSIMPREEMPTIONEN VGCS IM Preemption Enable
GLOBALROUTESW Global route management switch
GMSKDELAY Diversity Transmitter GMSK Delay
GPRS GPRS
GPRS Support GPRS
GPRSCELLRESELECTHYESTERESIS GPRS Cell Reselect Hysteresis
GPRSCHPRI PDCH Channel Priority Type
GPRSHCSTHR Threshold of HCS Signal Strength
GPRSPENALTYTIME GPRS Penalty Time
GPRSRXQUALLIMIT GPRS Quality Threshold
GPRSTEMPOFFSET GPRS Temporary Offset
GPSORGLONASS GPS or Glonass
GPSPERIOD GPS data report period
GRADEACCALLOW Grade Access Allow
GROUPCALLNUM1 Group Call Num 1
GROUPCALLNUM2 Group Call Num 2
GROUPINDEX BSC Node Redundancy Group Index
GROUPNAME BSC Node Redundancy Group Name
GROUPRELTSNUM Group Release TS Number
GRPID Transport Resource Group No.
GRPT Transport Resource Group Type
GS Geography Scope
GSMCSBWRATE CS ratio
GSMCSUSERHIGHPRILEV GSM CS High Level Standard
GSMFREQCNUM Serving Band Reporting
GSMTOTDALLOWED GSM-to-TD Cell Reselection Allowed
GUARDTYPE ICMP type which will be guarded
GWIP BTS SeGW IP Address
GWIP BTS Security Gateway IP Address
HalfRateDataSupport Support Half Rate Data Service
HALFTOFULLATCBOFFSET H-F ATCB Offset Overlay
HALFTOFULLHODURATION H-F Ho Duration
HALFTOFULLHOLASTTIME H-F Ho Last Time
HALFTOFULLHOPATHOFFSET H-F Pathloss Offset Overlay
HALFTOFULLHOSTATTIME H-F Ho Stat. Time
HAVETT1 Antenna Tributary 1 Flag
HAVETT2 Antenna Tributary 2 Flag
HBINTER Heartbeat interval
HCN Head Cabinet No.
HCSLASTTIME HCS HO Valid Time
HCSSTATTIME HCS HO Watch Time
HIERPWRPARA1 Hierarchical Power Para1
HIERPWRPARA2 Hierarchical Power Para2
HiFreqBandSupport Support High Frequency Band
HIGHESTPRIORITQUALFIRST Highest Priority for Quality First
HIGHLEVPREEM Highest-Priority MSs Rapid Preemption
HIGHPRIUSERQUALFIRST Highest Priority User Quality First
HIGHTEMPLOADPWROFF High Temp Load Power Off
HISPRIOALLOW History Record Priority Allowed
HISTORYPWDNUM Maximum History Password Numbers
HMCDTM Support HMC DTM
HOALGOPERMLAY Pref. Subcell in HO of Intra-BSC
HOBTWNOTHOPALLOW Handover Between Operators Allow
HOCDCMINDWPWR Min DL Level on Candidate Cell
HOCDCMINUPPWR Min UL Level on Candidate Cell
HOCELLIDTYPE Specify Index of Cell Handover to
HOCELLNAME Cell Name of Handover to
HOCTRLSWITCH Current HO Control Algorithm
HODIRFORECASTEN Handover Direction Forecast Enable
HODIRLASTTIME Handover Direction Forecast Last Times
HODIRSTATIME Handover Direction Forecast Statistic Times
HODOWNTRIGE Quick Handover Down Trigger Level
HODURT3G FDD 3G Better Cell HO Valid Time
HODURT3GTDD TDD 3G Better Cell HO Valid Time
HOECNOTH3G Ec/No Threshold for Better 3G Cell HO
HOLASTTIME Quick Handover Last Time
HOMOD Handover Scope
HOOFFSET Quick Handover Offset
HOOLRXLEVOFFSET Handover to Overlayer RxLev Offset
HOOPTSEL Inter-rat HO Preference
HOPENALTYTIME Inter UL/OL Subcells HO Penalty Time
HOPINDEX Hop Index
HOPINDEX Hop Index
HOPMODE Hop Mode
HOPOWERBOOST Power Boost before HO Enabled or Not
HOPRETH2G HO Preference Threshold for 2G Cell
HopSingleFreqOptSwitch Hop Group Single Freq Optimization
HOPTRXHSN Hop TRX Group HSN
HOPTRXINDEX Hop TRX Group Index
HOPTYPE Hop Type
HOPUNISHVALUE Quick Handover Punish Value
HOREFTMR BSC HO Protect Time
HORSCPTH3G RSCP Threshold for Better 3G Cell HO
HoSdcchSpeechVer Speech VER in SDCCH HO REQ ACK
HOSTAT3G FDD 3G Better Cell HO Watch Time
HOSTAT3GTDD TDD 3G Better Cell HO Watch Time
HOSTATICTIME Quick Handover Static Time
HOSTTYPE The host type of signalling point
HOSTTYPE HostType
HOTHRES Inter-layer HO Threshold
HOUPTRIGE Quick Handover Up Trigger Level
HPANTMODE Cell Antenna Hopping
HPANTMODE Cell Antenna Hopping
HPN Head Port No.
HPRIOR Highest Priority
HPVFLAG Hierarchical Power-off Config. Enabled
HPVTHD Load Power-off Voltage
HRATESPT Support Half Rate
HRDLDTX HR Use Downlink DTX
HRIUOLDRATESELALLOW Load of UL-OL Cells Rate Select Allowed
HRULDTX HR Uplink DTX
HSN HSN
HSN Head Slot No.
HSNSW HSN Modification Switch
HSRN Head Subrack No.
HT Hop Type
HTCP High Temperature Critical Point
HTDO High Temperature Delta Tout
HTSDF High Temperature Shutdown Flag
HUM_MASK Enable Humidity Alarm Reporting
HUM_THD_HIGH Upper Limit of Humidity Alarm
HUM_THD_LOW Lower Limit of Humidity Alarm
HUMALAMRTHRESHOLDH Upper Threshold of Humidity Alarm
HUMALAMRTHRESHOLDH Upper Threshold of Humidity Alarm
HUMALAMRTHRESHOLDL Lower Threshold of Humidity Alarm
HUMALAMRTHRESHOLDL Lower Threshold of Humidity Alarm
HYSON Hysteresis for On
IARXTMR Inactive RX timer
IASUDURAT Duration
IASUPORT Port No.
IASUSLCTTMU Transmission Board Type
IATXTMR Inactive TX timer
IBCAAFRSOFTBLKTHRD IBCA AMR FR Soft Block Threshold
IBCAAHRSOFTBLKTHRD IBCA AMR HR Soft Block Threshold
IBCAALLOWED IBCA Allowed
IBCAASSWAITMEASURERPTTIME IBCA Assign Waiting Mr Time
IBCACALLINFOFILTERLEN IBCA Call Information Filter
IBCACALLSOFTBLOCKTHOFFSET IBCA Set-up Call Soft Block Threshold Offset
IBCACALLTARGETCIROFFSET Target CIR Offset of IBCA Set-up Call
IBCADLPATHLOSSOFF IBCA Downlink Path Loss Offset
IBCADYNCMEASURENCELLALLOWED IBCA Dyn Measure Neighbour Cell Flag
IBCAEHOASSWAITMEASURERPTTIME IBCA Urgent HO Waiting Mr Time
IBCAFLEXTSCALLOWED IBCA Flexible TSC Allowed
IBCAFORCEDBTSSYNCALLOWED IBCA Forced BTS Synchronization Allowed
IBCAFRSOFTBLKTHRD IBCA FR/EFR Soft Block Threshold
IBCAHOASSWAITMEASURERPTTIME IBCA HO Waiting Effective Mr Time
IBCAHRSOFTBLKTHRD IBCA HR Soft Block Threshold
IBCAICDMRELEVOFFSET IBCA ICDM Initial Level Offset
IBCAICDMSWITCH IBCA ICDM Switch
IBCAINBSCINFORPTPRD IBCA Info Report Period Within BSC
IBCAINITPCRXLEVDLOFFSET IBCA Init. Power Control RexLevDL Offset
IBCAINITPCRXLEVULOFFSET IBCA Init. Power Control RexLevUL Offset
IBCAINITPCRXQUALDLOFFSET IBCA Init. Pwr Ctrl Rx Qual DL Offset
IBCAINITPCRXQUALULOFFSET IBCA Init. Pwr Ctrl Rx Qual UL Offset
IBCAIUOPATHLOSSOFF IBCA IUO Path Loss Offset
IBCAMAIOUSMTD IBCA MAIO Using Method
IBCAMAXINTFSRCNUM IBCA Max. Interference Source Num.
IBCANCELLFLAG IBCA Neighbor Cell Flag
IBCANCELLPATHLOSSESTIMATE IBCA Pathloss Est of Non. MR Ncell
IBCANEWCALLCIROFFSET Target CIR Offset of IBCA New Call
IBCANHOASSWAITMEASURERPTTIME IBCA Natural HO Waiting Mr Time
IBCANONMEANCELLSTATNUM IBCA Non Measurement Ncell Stat. Num
IBCAOPRREVISEFACTOR Corrected Factor of IBCA Priority
IBCAOUTBSCINFORPTPRD IBCA Info Report Period Between BSC
IBCAPATHLOSSOFF IBCA Pathloss Offset
IBCAPLFILTFACTOR IBCA Path Lose Filter Factor
IBCARXLEVOFFSET IBCA RxLev Offset
IBCASCELLPATHLOSS IBCA Service Cell Pathloss
IBCASOFTBLKSAICOFF IBCA Soft Block SAIC Offset
IBCASOFTBLKSWITCH IBCA Soft Block Switch
IBCASUBCHNHANDOVERALLOWED IBCA Sub-Channel Handover Allowed
IBCATARGETCIRTHRSH IBCA MAIO Target C/I Threshold
IBCAUSEDIUOSUBLAY IUO IBCA Allowed
IBCAUSRDYNCMEASURENCELL IBCA User Dyn Measure Neighbor Cell
IBCAWAFRSOFTBLKTHRD IBCA WAMR FR Soft Block Threshold
ICBALLOW ICB Allowed
ICF Intelligent Control Flag
ICMPPKGLEN ICMP packet Length
ICTHP1DSCP DSCP of PRI.1 INTACT[QoS]
ICTHP2DSCP DSCP of PRI.2 INTACT[QoS]
ICTHP3DSCP DSCP of PRI.3 INTACT[QoS]
ID Task ID
ID Task ID
ID Index
Idle_Code Idle Code
IDLECODE Idle code
IDLESDTHRES Idle SDCCH Threshold N1
IDTYPE Index Type
IDTYPE BTS Index Type
IDTYPE Index Type
IDTYPE Index Type
IDTYPE Index Type
IDTYPE Index Type
IDTYPE Index Type
IDTYPE Index Type
IDX Semipermanent Link Index
IDXTYPE Index Type
IDXTYPE Index Type
IFCBSHAKEHAND If CB Shake Hand
IFNO Outgoing Interface No.
IFOFFSETHIG Positive or Minus Offset
IFOFFSETLOW Indication Offset
IFREPPRO Report Process Flag
IGNOREMRNUM Ignore Measurement Report Number
IMEI IMEI
IMMASSAINTERFTIMER IMM ASS A IF Creation Timer
IMMASSCBB Immediate Assignment Optimized
IMMASSDLSHIFT Move Immediate Assignment Down to BTS
IMMASSEN TCH Immediate Assignment
IMMASSMAXDELAYTIME Max Delay of IMM ASS Retransmit
IMMASSMAXSENDNUM Max Transmit Times of IMM ASS
IMMASSRESENDEN Use IMM ASS Retransmit Parameter
IMMASSTAALLOW TA Pref. of Imme-Assign Allowed
IMMASSTATHRES TA Threshold of Imme-Assign Pref
IMMFNAD Immediate Initial Adjust After Site Reset Enable
IMMREJWAITINDTIMER T3122
IMSI IMSI
IMSI IMSI
INBSCHOTIMER T3121
INCHLOD Fine Tuning Threshold
INCHPRD Fine Tuning Period in BSC
INCLUDEANG Included Angle
INCN In Port Cabinet No.
INDEN3 Independent E1 Port 3
INFHHOLAST Intracell F-H HO Last Time
INFHHOSTAT Intracell F-H HO Stat Time
INFOEXCHGLIST Info Exchange Content
INFRA_RED_MASK Infrared alarm switch
INHOF2HTH F2H HO Threshold
INHOH2FTH H2F HO Threshold
INHOPWROVERLOADTHRESHOLD Power Overload Threshold In Ho. In
INITCDMDF AMR Starting Mode[F]
INITCDMDH AMR Starting Mode[H]
INITCDMDWB AMR Starting Mode[WB]
INMASK In BSC Mask
INNASSOPTEN OL Subcell Assignment Optimization
INNCELLEDGEHOEN Inner Cell EDGE HO Enable
INNCELLID BSC Inner Cell Index
INNCELLNAME BSC Inner Cell Name
INNLOADHOEN Load HO of OL Subcell to UL Subcell
INNLOADHOPERI OL Subcell Load Diversity HO Period
INNLOADHOSTEP Step Length of OL Subcell Load HO
INNSERIOVERLDTHRED Inner Cell Serious OverLoad Thred
INPN In BSC Port No.
INPN BTS In Port No.
INPORTNO DXX In Port No.
INPUTMD Latitude and Longitude Input Mode
INRBSCSDHOEN Inter-BSC SDCCH HO ALLowed
INSN In BSC Slot No.
INSN In Port Slot No.
INSRN In BSC Subrack No.
INSRN In Port Subrack No.
INT Broadcast Interval
INTELEVHOHYST Adjacent Cell Inter-layer HO Hysteresis
INTERBANDSTATALGO Interfere Band Stat Algorithm Type
INTERCELLHYST Inter-cell HO Hysteresis
INTERFEREHOPENTIME Penalty Time on Interfere HO
INTERFERELASTTIME Interfere HO Valid Time
INTERFERESTATTIME Interfere HO Static Time
INTERFHOEN Interference HO Allowed
INTERFPRIALLOW Interf. Priority Allowed
INTERFTHRES0 Interference Band Threshold 0
INTERFTHRES1 Interference Band Threshold 1
INTERFTHRES2 Interference Band Threshold 2
INTERFTHRES3 Interference Band Threshold 3
INTERFTHRES4 Interference Band Threshold 4
INTERFTHRES5 Interference Band Threshold 5
INTERIORSYNCTMR BSC Interior Clock Synchronize Protect Time
INTERPERIOD Interference Calculation Period
INTERRATCELLRESELEN Inter-RAT Cell Reselection Enable
InterRatCsServiceLoadHoThrd Inter-RAT CS Service HO Load Threshold
INTERRATINBSCHOEN Inter-RAT In BSC Handover Enable
InterRatIurgInBscHoEn Allow Incoming BSC Handover at Iur-g
InterRATLoadHoEcNoBandWidth Inter-RAT Load HO Bandwidth [EcNo]
InterRATLoadHoEcNoStart Inter-RAT Load HO EcNo at Start Point
InterRATLoadHoEcNoStep Inter-RAT Hierarchy Load HO Step [EcNo]
InterRATLoadHoRSCPBandWidth Inter-RAT Load HO Bandwidth [RSCP]
InterRATLoadHoRSCPStart Inter-RAT Load HO RSCP at Start Point
InterRATLoadHoRSCPStep Inter-RAT Hierarchy Load HO Step [RSCP]
INTERRATOUTBSCHOEN Inter-RAT Out BSC Handover Enable
InterRatServiceLoadHoSwitch Allow Inter-RAT Load HO in Access State
INTERVAL Relative Time
INTERVAL Send PKT Interval[s]
INTFREQUENCY Interference Frequency
INTOINNREXLEVTHRED Incoming OL Subcell HO Level TH
INTRABSCCODECHOCMDTIMER T25
INTRABSCHOTIMER T3103A
INTRACELLFHHOEN Intracell F-H HO Allowed
INTRACELLHOEN Intracell HO Allowed
INTRACELLHOTIMER T3103C
INTRAMBSC Co-MBSC
IntRATLoadHOEcNoThr Inter-RAT Load HO EcNo Threshold
IntRATLoadHoPeriod Inter-RAT Hierarchical Load HO Period
IntRATLoadHORSCPThr Inter-RAT Load HO RSCP Threshold
INTSN In BSC Start Timeslot No.
INTSNO DXX In Time Slot No.
INTV Time Interval
INTV OMU Automatic Switchover Interval
INVALBSICEN Invalid BSIC Reporting
IP IP Address
IP IP Address
IP Local IP Address
IP Remote IP Address
IP Physical IP
IP FTPServer IP
IPADDR Local IP address
IPADDR IP address
IPADDR Local IP address
IPADDR Packet source IP address
IPADDR Next Hop IP address.
IPADDR Local IP address
IPADDR IP Address
IPADDR1 IP Address1
IPADDR1 Master Clock Server IP Address
IPADDR2 IP Address2
IPADDR2 Slave Clock Server IP Address
IPADDR3 IP Address3
IPADDR4 IP Address4
IPEAAT IP Frame Error Alarm Threshold
IPEADT IP Frame Error Alarm Clearance Threshold
IPHC Head compress
IPHC Head compress
IPINDEX IP address index
IPINDEX IP address index
IPMUXINDEX IP MUX Index
IPPHYTRANSTYPE IP Phy Trans Type
IPPHYTRANSTYPE IP Physical Tran. Type
ISADDEDTMPCONTROL DHEU Heater Control Allowed
ISBASICBSC Base BSC
ISCHAINNCELL Chain Neighbor Cell
ISCLKREDUCY Clock Server Redundancy
ISCLKREDUCYBAK Clock Server Redundancy
ISCONFIGEDRING Config Ring
ISCONFIGTHD Configure Check Thresholds or Not
ISEDGESUPPORT EDGE Support in External Neighbour Cell
ISFIRSTCLASS Is First Class Transport Resource Group
ISGPRSSUPPORT GPRS Support in External Neighbour Cell
ISMAINBCCH Is Main BCCH TRX
IsMainBSC Is Main BSC
ISMAINLOCGRP Is Main Local Group
ISNC2SUPPORT NC2 Support in External Neighbour Cell
ISNCMODE Subnetwork Configure Mode
ISQOSPATH IS QOSPATH
ISSPTBSCAISS Support BSC AISS
ISSPTDEMUS Demu Configure Information
ISSUPERBTS Is Supper BTS
ISSUPPORTBTSLSWITCH Support BTS Local Switch
IsSupportTcPool Is Support Tc Pool
ISTCBRD TC board
ISTCCENTRAL Remote TC Central
ISTMPCTRL DHEU Temperature Control
ISTRANCABCON Tran. Cabinet Configured
ITEM NCCELL No.
ITEMINDEX Item Index
ITEMVALID Item Valid
ITEMVALUE Value
ITFT Interface Type
ITFType Interface Type
IUO Concentric Attribute
Dynamic Channel Conversion Parameter of Concentric
IUOCHNTRAN Cell
IUOHODURATIME UO HO Valid Time
IUOHOSTATIME UO HO Watch Time
IUOTP Cell IUO Type
J0ALMSWITCH J0 trace mismatch alarm switch
J0BYTE_FORMAT J0 Byte Format
J0RXVALUE J0 expected incept value
J0TXVALUE J0 transmit value
J0TYPE J0 type
J1ALMSWITCH J1 trace mismatch alarm switch
J1BYTE_FORMAT J1 Byte Format
J1RXVALUE J1 expected incept value
J1TXVALUE J1 transmit value
J1TYPE J1 type
J2ALMSWITCH J2 mismatch alarm switch
J2BYTE_FORMAT J2 Byte Format
J2MODE J2 length
J2RXVALUE J2 expected incept value
J2TXVALUE J2 transmit value
JAUTOADD Automatic Append J Byte
JBF LAPD Jitter Buffer Algorithm
JITBUFDELAY PS Jitter Buffer Delay
JITBUFSWITCH Jitter Buffer switch
K2MODE K2 Mode
KBIAS K Bias
KEEPALIVE Keep-alive timer length[S]
LAC Cell LAC
LAC1 Cell LAC
LACPMODE Aggregation Mode
LATIDECI Latitude Decimal Part
LATIDEGREE Latitude Degree Part
LATIINT Latitude Int Part
LATIMINUTE Latitude Minute Part
LATISECONDDECI Latitude Second Decimal Part
LATISECONDINT Latitude Second Int Part
LATITUDE GPS antenna latitude
LATITUDESEC GPS antenna latitude
LATPRD Delay measure period [100ms]
LATSUSTM Delay adjust suspend period [LATTH]
LATTH Rate down threshold for delay [ms]
LATUDK average delay down filter mantissa
LATUPK average delay up filter mantissa
LAYER Layer of The Cell
LAYER Layer of the cell
LAYHOLOADTH Inter-Layer HO Load Threshold
LBCongestProtect1 Lb Congestion Protection Timer 1
LBCongestProtect2 Lb Congestion Protection Timer 2
LDRFOUH LDR Fourth
LDRFST LDR First
LDRSND LDR Second
LENO Local entity No.
LEVEL Log Level
LEVEL Log Level
LEVEL Alarm Mask Switch
Level MD LEVEL
LEVELRPT Level Report Switch
LEVHOEN Level HO Allowed
LEVHOHYST Inter-layer HO Hysteresis
LEVLAST Layer HO Valid Time
LEVSTAT Layer HO Watch Time
LGCAPPTYPE Logical function type
LGCAPPTYPE Logical function type
LGCAPPTYPE Logic function type
LGCUSAGETYPE Application type of POUc_TDM
LGIDX PbSL Logical Index
LHUMTHD Lower Humidity Threshold
LICALMCTHD Alarm occur threshold
LICALMRTHD Alarm recover threshold
LINKNO Link No.
LISTTYPE Query Type
LKTATE Link rate type
LL Lower Limit
LL Lower Limit
LLCN Channel No.
LNA1 LNA Threshold1
LNA2 LNA Threshold2
LNKNUMMODE Tributary Numbering
LNKRATE Semipermanent Link Rate
LNKREDFLAG Initial bearing traffic active tag
LNKSLSMASK Signalling link mask
LNKSLSMASK Signalling link mask
LoadAccThres Load handover Load Accept Threshold
LOADBALANCEALG MSC Pool Load Balancing Algorithm Select
LOADBROADCASTPERIOD NC2 Load Broadcast Period
LOADCURRENTDIV Load Current Shunt Coefficient
LOADHOAD Enhanced Load HO Allowed
LoadHoEn Load Handover Support
LoadHoEnExt2G Load Handover Support
LoadHoEnExt3G Load Handover Support
LOADHOPBGTMARGIN Load HO PBGT Threshold
LOADHOPENTIME Penalty Time on Load HO
LOADHOPENVALUE Penalty Value on Load HO
LOADHOPERIOD Load HO Step Period
LOADHOSTEP Load HO Step Level
LOADHOUSRRATIO HO Ratio of Enhanced Load HO Algorithm
LOADOFFSET Load HO Bandwidth
LOADPWROFFEN Load Power-off Allowed State
LOADRESELALLOW Cell Load Reselection Allowed
LOADRESELMAXRXLEV Load Reselect Level Threshold
LOADRESELRXTHRSH Load Reselection Receive Threshold
LOADRESELSTARTTHRSH Load Reselection Start Threshold
LOADSHAREALLOW Balance Traffic Allowed
LOADSTATYPE Type of Cell Load Calculation
LOADTHSW TRM Load Threshold switch
LocalBSCID Local BSC ID
LOCALIP Local IP address
LOCALIP Local IP address
LOCALIP Local IP Address
LOCALIP Local IP Address
LOCALNSVLI Local NSVL ID
LOCALPORTNO Local Port No.
LOCGRPNO Location Group No.
LOCGRPNO Location Group No.
LOCINFOKEY Filter of Location Information
LOCIP1 First local IP address
LOCIP2 Second local IP address
LOCKST Set Locked/Unlock
LOCPN Local SCTP port No.
LODCTRL Board Start Load Control.
LODMODE Loading Mode
LOGCTHD Log control threshold
LOGCTHD Log control threshold
LOGPORTFLAG Logic Port Flag
LOGPORTNO Logic Port No.
LOGPORTSN Logic Port Slot No.
LOGRTHD Log restore threshold
LOGRTHD Log restore threshold
LOGSW Log control switch
LOGTYPE Log File Type
LOGTYPE Log Type
LONGIDECI Longitude Decimal Part
LONGIDEGREE Longitude Degree Part
LONGIINT Longitude Int Part
LONGIMINUTE Longitude Minute Part
LONGISECONDDECI Longitude Second Decimal Part
LONGISECONDINT Longitude Second Int Part
LONGITUDE GPS antenna longitude
LONGITUDESEC GPS antenna longitude
LoopLevel Loop Level
LOOPMODE Loopback Type
LOOPSW Loop Detect Switch
LOOPTYPE Loop type
LOOSESDCCHLOADTHRED IBCA Loose Trx SDCCH Load Threshold
LOPDIR Loop Direction
LOPLOC Loop Position
LOPT Loop type
LOPT Loop type.
LOPTIME Loop Time
LOSTSUSTM Suspend times after bandwidth adjusted
LOWLEVSUBRESPREEMPTFLG Low-level Sublink Resource Preempt Switch
LOWLEVSUBRESPREEMPTFLG Low Lev Sub Res Preempt Flag
LOWNOISESWH Diversity LNA Bypass Permitted
LOWRXLEVOLFORBIDSWITCH Allocate OL Channel Based on RX Level
LOWTEMPLOADPWROFF Low Temperature StartLoadPower-off Allowed State
LOWTEMPLOADPWROFF Low Temperature StartLoadPower-off Allowed State
LPBKMODE Loop Back Mode
LPN IP Logic Port No.
LPN Logic port No.
LPN Logic port No.
LPNSN IP Logic Port Slot No.
LPNTYPE Type of the logic port
LQCMODE Link Quality Control Mode
LSDF Load Shutdown Flag
LSDV Load Shutdown Voltage
LSRTRD LDR Third
LSTCMD Whether Include List Command
LstFormat Result list format
LSTFORMAT Result List Format
LT Load type
LT Log Type
LT Log Type
LTCP Low Temperature Critical Point
LTEMTHD Lower Temperature Threshold
LTFERLOWTH Uplink Long-term FER Lower Threshold
LTFERTGT Uplink Long-term FER Target
LTFERUPTH Uplink Long-term FER Upper Threshold
LTTHADJFA Uplink Threshold Adjust Factor
LVDS252DSPNUM Number of DSPs with 252 LVDS Links
Lvl1Vswr Lvl1 Vswr
Lvl2Vswr Lvl2 Vswr
LVSDF Low Voltage Shutdown Flag
M3UASRVPN M3UA service listening port No.
MAC MAC Address
MACEAAT MAC Frame Error Alarm Threshold
MACEADT MAC Frame Error Alarm Clearance Threshold
MACODINGMOD ARFCN Coding Scheme
MAIDX MA Index
MAINBCCHPWDTACTCHEN Power Derating Active Channel Enabled
MAINBCCHPWRDTEN Power Derating Enabled
MAINBCCHPWRDTETIME Power Derating End Time
MAINBCCHPWRDTRANGE Power Derating Range
MAINBCCHPWRDTSTIME Power Derating Start Time
MAINDEVTAB BTS Interface Board Bar Code 1
MAINDEVTAB PTU Main Dev. Tab
MAINLOCGRPNO Main Location Group No.
MAINPORTNO Main Port No
MainVer Main Version No.of TMU
MAIO1 MAIO 1
MAIO10 MAIO 10
MAIO11 MAIO 11
MAIO12 MAIO 12
MAIO2 MAIO 2
MAIO3 MAIO 3
MAIO4 MAIO 4
MAIO5 MAIO 5
MAIO6 MAIO 6
MAIO7 MAIO 7
MAIO8 MAIO 8
MAIO9 MAIO 9
MAJORALMUP0 Feed Tri. 0 TMA Over Critical Alarm Threshold
MAJORALMUP1 Feed Tri. 1 TMA Over Critical Alarm Threshold
MAJORALMUP2 Feed Tri. 2 TMA Over Critical Alarm Threshold
MAJORALMUP3 Feed Tri. 3 TMA Over Critical Alarm Threshold
MAJORALMUP4 Feed Tri. 4 TMA Over Critical Alarm Threshold
MAJORALMUP5 Feed Tri. 5 TMA Over Critical Alarm Threshold
MANAME MA Name
MANAME MA Name
MASK Subnet mask
MASK Subnet mask
MASK Subnet mask
MASK Packet source mask
MASK Subnet mask
MASK Mask
MASK IP Mask
MASK Subnet Mask
MASK Subnet Mask
MASTERIPADDR Master Clock Server IP Address
MASTERIPADDR Clock Server IP Address 1
MAXADJPCVAL MAX Up Adj. PC Value by Qual.
MAXASSOCRETR Association max retrans
MAXBW Max bandwidth [64kbps]
MAXCNTNUM MAX Consecutive HO Times
MaxDlAssRetryTimes Retry Times of Downlink TBF Reassignment
MaxDlEstRetryNum Retry Times of Downlink TBF Establishment
MAXDROPPWRTHRESHOLD Max Drop Power Threshold
MAXFQNUM Maximum TRX Number
MAXFQNUM1 Maximum TRX Number
MAXFRAMELEN Maximum Frame Length[byte]
MAXLOADBTSNUM Max BTS Num of Parallel Software Load
MAXMFLEN PPP mux max mux-frame length
MAXMFLEN PPP mux max mux-frame length
MaxMissTimes Maximum Retry Times
MAXNUM Max Alarm Log Number
MAXOUTPUTPOWER Diesel Max Output Power
MAXPATHRETR Path max retrans
MaxPbLinkChkNum Pb Link Check Max TimeOut Number
MAXPDCHNUM Maximum Number of PDCH
MAXPDCHRATE Maximum Rate Threshold of PDCHs in a Cell
MaxPollingRetryTimes Retry Times of Downlink TBF Polling
MAXPROMPTDATES Expire Prompt Dates
MAXRECHARGECURRENT Charge Coefficient
MAXRECHARGECURRENT Charge Coefficient
MAXRESEND Max Resend Times of Phy.Info.
MAXRETRANS1 Max Retransmissions for Radio Priority 1
MAXRETRANS2 Max Retransmissions for Radio Priority 2
MAXRETRANS3 Max Retransmissions for Radio Priority 3
MAXRETRANS4 Max Retransmissions for Radio Priority 4
MAXSFLEN PPP mux max sub-frame length
MAXSFLEN PPP mux max sub-frame length
MAXSTEP0 MAX Down Adj.Value Qual.Zone 0
MAXSTEP1 MAX Down Adj.Value Qual.Zone 1
MAXSTEP2 MAX Down Adj.Value Qual.Zone 2
MAXTA Max TA
MAXTADROPCALLFILTER MAX TA Drop Call Filter
MAXTADROPCALLSWITCH Max TA Drop Call Switch
MAXTADROPCALLTHRESHOLD MAX TA Drop Call Threshold
MAXTIME Maximum time for posave
MAXTSOCP Maximum Number of Occupied Abis Timeslots
MAXTTL MAX TTL
MAXVALADJRX MAX Up Adj. PC Value by RX_LEV
MAXVALIDDATES Maximum Valid Dates
MBFDCHKN MBFD Check Index
MBFDLOCALIP Multi hop BFD detect local ip
MBR Multi-band report
MBSIGNLEN Filter Length for SDCCH MEAN_BEP
MBTRAFFLEN Filter Length for TCH MEAN_BEP
MBTSID Second BTS Index
MBTSNAME Second BTS Name
MCC MCC
MCC1 Cell MCC
MCCLASS MC PRI number
MCCLASS MC PRI Number
MCELLID Second Cell Index
MCELLNAME Second Cell Name
MCN Cabinet No. of Management Board
MCPAOPTALG MCPA Optimization Switch
MCSTANDARD GSM Multi Carrier BTS Standard
MDIDX MD INDEX
MDLEVEL MD Level
MDName MD NAME
MDNAME MD Name
MEASORDER Allow MR Command or not
MEASPERIOD Measurement Period
MEASURETYPE Measurement Report Type
MEPID MEP ID
MEPID MEP ID
MEPTYPE MEP Type
MHF MP/MC list head option
MHF MP/MC List Head Option
MINACCRXLEV Cell Reselection Level Threshold
MINBW Min bandwidth [64kbps]
MINECNOTHRES Min Ec/No threshold
MINOFFSET Min Access Level Offset
MinorAlmThdA ANT_A ALD Current Minor Alarm Occur Threshold
MinorAlmThdB ANT_B ALD Current Minor Alarm Occur Threshold
MINORALMUP0 Feed Tri. 0 TMA Over Warning Alarm Threshold
MINORALMUP1 Feed Tri. 1 TMA Over Warning Alarm Threshold
MINORALMUP2 Feed Tri. 2 TMA Over Warning Alarm Threshold
MINORALMUP3 Feed Tri. 3 TMA Over Warning Alarm Threshold
MINORALMUP4 Feed Tri. 4 TMA Over Warning Alarm Threshold
MINORALMUP5 Feed Tri. 5 TMA Over Warning Alarm Threshold
MinorClrThdA ANT_A ALD Current Minor Alarm Clear Threshold
MinorClrThdB ANT_B ALD Current Minor Alarm Clear Threshold
MINPWRLEVDIRTRY Min Power Level For Directed Retry
MINRESTIMETCH TCH Minimum Recovery Time
MINRSCPTHRES Min RSCP threshold
MINRXINT Min interval of BFD packet receive [ms]
MINRXINTERVAL Minimum RX Interval
MINTXINT Min interval of BFD packet send [ms]
MINTXINTERVAL Minimum TX Interval
MIRRORDPN Mirror Dest Port No.
MIRRORSPN Mirror Source Port No.
MIRRORTYPE Mirror Type
MNC MNC
MNC1 Cell MNC
MOCACCESSCPURATE MOC Access CPU Rate
MODE System clock working mode
MODE Signalling link mode
MODE Configure Mode
MODE Mode after Switchover
MODE File Output Mode
MODE Backup mode
MODE Check mode
MODE0 Feed Tri. 0 Alarm Mode
MODE1 Feed Tri. 1 Alarm Mode
MODE2 Feed Tri. 2 Alarm Mode
MODE3 Feed Tri. 3 Alarm Mode
MODE4 Feed Tri. 4 Alarm Mode
MODE5 Feed Tri. 5 Alarm Mode
MONITORPERIOD Monitor Period
MONITORTIME Monitor Time
Month Month
MOVESPEEDTHRES Quick Move Speed Threshold
MPGRPEAAT MP Group Frame Error Alarm Threshold
MPGRPEADT MP Group Frame Error Alarm Clearance Threshold
MPGRPN MP Group No.
MPGRPN MP Group No.
MPGRPN MLPPP Group No.
MPMODE Multiplexing Mode
MPN Connect Port No.
MPSWITCH MCPPP Switch
MPTYPE MP type
MPUSLOT MPU Slot No.
MPUSUBRACK MPU Subrack No.
MRCOMPREG MR. Compensation Allowed
MRMISSCOUNT Allowed MR Number Lost
MRMISSNUM MRMissNumber
MRPREPROCFREQ Sent Freq.of preprocessed MR
MRRUATTENFACTOR1 Antenna Tributary 1 Factor
MRRUATTENFACTOR2 Antenna Tributary 2 Factor
MRSCOPESWITCH MR Collection Scope Switch
MRSWITCH MR Collection Control Switch
MRU Max Receive Unit
MS Number of MSs
MSCAPABLESTATSWITCH MS Capability Statistic Switch
MSCCAP MSC Available Capability<K User number>
MSCNRILEN Length of NRI in TMSI
MSCNULLNRI MSC NULL-NRI Value
MSCPOOLALLOW MSC Pool Function Enabled
MSCSTATUE MSC Administrable State
MSCVER MSC Version Indication
MSIPFAILINDDELAY TREESTABLISH
MSISDN MSISDN
MSISDNPREFIX1 MSISDN prefix 1
MSISDNPREFIX2 MSISDN prefix 2
MSISDNPREFIX3 MSISDN prefix 3
MSISDNPREFIX4 MSISDN prefix 4
MSISDNPREFIX5 MSISDN prefix 5
MsisdnPrfxList2StartBscLs1 Prefix Number for BSC 1
MsisdnPrfxList2StartBscLs10 Prefix Number for BSC 10
MsisdnPrfxList2StartBscLs2 Prefix Number for BSC 2
MsisdnPrfxList2StartBscLs3 Prefix Number for BSC 3
MsisdnPrfxList2StartBscLs4 Prefix Number for BSC 4
MsisdnPrfxList2StartBscLs5 Prefix Number for BSC 5
MsisdnPrfxList2StartBscLs6 Prefix Number for BSC 6
MsisdnPrfxList2StartBscLs7 Prefix Number for BSC 7
MsisdnPrfxList2StartBscLs8 Prefix Number for BSC 8
MsisdnPrfxList2StartBscLs9 Prefix Number for BSC 9
MsisdnPrfxList2StartBtsLs1 Prefix Number for BTS 1
MsisdnPrfxList2StartBtsLs10 Prefix Number for BTS 10
MsisdnPrfxList2StartBtsLs2 Prefix Number for BTS 2
MsisdnPrfxList2StartBtsLs3 Prefix Number for BTS 3
MsisdnPrfxList2StartBtsLs4 Prefix Number for BTS 4
MsisdnPrfxList2StartBtsLs5 Prefix Number for BTS 5
MsisdnPrfxList2StartBtsLs6 Prefix Number for BTS 6
MsisdnPrfxList2StartBtsLs7 Prefix Number for BTS 7
MsisdnPrfxList2StartBtsLs8 Prefix Number for BTS 8
MsisdnPrfxList2StartBtsLs9 Prefix Number for BTS 9
MsisdnSegList2AvoidBscLs1 Avoid Number for BSC 1
MsisdnSegList2AvoidBscLs10 Avoid Number for BSC 10
MsisdnSegList2AvoidBscLs2 Avoid Number for BSC 2
MsisdnSegList2AvoidBscLs3 Avoid Number for BSC 3
MsisdnSegList2AvoidBscLs4 Avoid Number for BSC 4
MsisdnSegList2AvoidBscLs5 Avoid Number for BSC 5
MsisdnSegList2AvoidBscLs6 Avoid Number for BSC 6
MsisdnSegList2AvoidBscLs7 Avoid Number for BSC 7
MsisdnSegList2AvoidBscLs8 Avoid Number for BSC 8
MsisdnSegList2AvoidBscLs9 Avoid Number for BSC 9
MsisdnSegList2AvoidBtsLs1 Avoid Number for BTS 1
MsisdnSegList2AvoidBtsLs10 Avoid Number for BTS 10
MsisdnSegList2AvoidBtsLs2 Avoid Number for BTS 2
MsisdnSegList2AvoidBtsLs3 Avoid Number for BTS 3
MsisdnSegList2AvoidBtsLs4 Avoid Number for BTS 4
MsisdnSegList2AvoidBtsLs5 Avoid Number for BTS 5
MsisdnSegList2AvoidBtsLs6 Avoid Number for BTS 6
MsisdnSegList2AvoidBtsLs7 Avoid Number for BTS 7
MsisdnSegList2AvoidBtsLs8 Avoid Number for BTS 8
MsisdnSegList2AvoidBtsLs9 Avoid Number for BTS 9
MSLEVSTRQPBGT EN Quick PBGT HO ALG When MS Leaves BTS
MSMAXRETRAN MS MAX Retrans
MSPCMD MSP Control Command
MSRDMCSLEV MSRD MCS Threshold
MSRDPDCHLEV MSRD PDCH Multiplex Threshold
MSRN Subrack No. of Management Board
MSRXMIN Min DL level on candidate Cell
MSRXQUALSTATTHRSH MS Rx Quality Statistic Threshold
MSTF MS Flow Control Timer
MSTSERVACTDELAY Master Service Active Delay
MSTXPWRMAX Maximum TX Power for Access PCH
MSW Self-healing Switch for Memory Overload
MTCACCESSCPURATE MTC Access CPU Rate
MTHD Method
MTP2LNKN MTP2 link No.
MTRLGY Metrology
MTU MTU value
MTU MTU[Byte]
MTU MTU
MTVT Hierarchical Power Supply Para.<0.1v>
MULTIBANDREP Multi-Band Report
MUTECHECKCLASS1PERIOD Period of Mute Detect Class1
MUTECHECKCLASS2SWITCH Mute Detect Class2 Switch
MUTECHECKPEIROD Period of Mute Detect Class2
MUTEFORBITCALLTMINTVAL Access Prohibited Upon One-Way Audio
Forced Call Release Upon Failed Handover in One-
MUTERELCALLEN Way Audio
MUXTIME PPP mux framing out-time[us]
MUXTIME PPP mux framing out-time[us]
MUXTYPE IP MUX Type
MWTRXNO Min Quantity of Working TRXs
MYDISCRIMINATOR My discriminator of BFD
N200 N200
N200ESTAB N200 of Establish
N200FFULL N200 of FACCH/Full Rate
N200FHALF N200 of FACCH/Half Rate
N200PARASWITCH Use LAPDm N200
N200REL N200 of Release
N200SACCH N200 of SACCH
N200SDCCH N200 of SDCCH
N3101 Maximum Value of N3101
N3103 Maximum Value of N3103
N3105 Maximum Value of N3105
N391 Parameter of DTE [N391]
N392 Parameter of DTE [N392]
N393 Parameter of DTE [N393]
NACCSPT Support NACC
NAME OSP name
NAME DSP name
NAME Signalling Route name
NAME Signalling link set name
NAME Signalling link name
NAME Adjacent Node Name
NAME Local entity name
NAME Destination entity name
NAME M3UA route name
NAME M3UA Signalling link set name
NAME M3UA Signaling link name
NAME PCU Name
NAMRLFRMTRXALLOWED Assign Non-AMR User Loose Fre. Reuse TRX
NAVGI N_AVG_I
NBAMRTFOSWITCH TFO Switch
NBR2GNCELL1ID Neighbor 2G Cell 1 Index
NBR2GNCELL1NAME Neighbor 2G Cell 1 Name
NBR2GNCELL2ID Neighbor 2G Cell 2 Index
NBR2GNCELL2NAME Neighbor 2G Cell 2 Name
NBR2GNCELLID Neighbor 2G Cell Index
NBR2GNCELLNAME Neighbor 2G Cell Name
NBR3GNCELLID Neighbor Cell Index
NBR3GNCELLNAME Neighbor Cell Name
NBRCELLSWITCH Neighbor Cell Plan Switch
NBRCI Neighbour Cell CI
NBRLAC Neighbour Cell LAC
NBRMCC Neighbour Cell MCC
NBRMNC Neighbour Cell MNC
NBRSPT64 Support 64 Neighbour Cells
NC2LoadResel NC2 Load Reselection Switch
NC2SPT Support NC2
NCC NCC
NCC NCC
NCCPERMIT NCC Permitted
NCCPERMITED NCC Permitted
NCELLFILTER Neighbor Cell Filter Length MR Number
NCELLFLTLEN Filter Length for Ncell RX_LEV
NcellInterFLevelThres0 NeighborCell Interfere Level Thresh 0
NcellInterFLevelThres1 NeighborCell Interfere Level Thresh 1
NcellInterFLevelThres2 NeighborCell Interfere Level Thresh 2
NcellInterFLevelThres3 NeighborCell Interfere Level Thresh 3
NcellInterFLevelThres4 NeighborCell Interfere Level Thresh 4
NcellInterFLevelThres5 NeighborCell Interfere Level Thresh 5
NcellInterFLevelThres6 NeighborCell Interfere Level Thresh 6
NcellInterFLevelThres7 NeighborCell Interfere Level Thresh 7
NCHOCBLOCKNUM NCH Occupy Block Number
NCHSTARTBLOCK NCH Start Block
NCO Network Control Mode
NEIGHBOR Adjacent flag
NETMASK Net Mask
NEWURGHOMININTV Min Interval for Emerg. HO
NEXTHOP Forward Route Address
NEXTHOP Forward route address
NEXTHOP Forward route address
NEXTHOP Forward Route Address
NI Network ID
NM Download file name
NMO Network Operation Mode
NMSACN No Mains Supply Alarm Cabinet No.
NMSAPN No Mains Supply Alarm Port No.
NMSASN No Mains Supply Alarm Slot No.
NMSASRN No Mains Supply Alarm Subrack No.
NO1M48ALMTHDDOWN Lower limit of No.1 input -48V[-V]
NO1M48ALMTHDUP Upper limit of No.1 input -48V[-V]
NO2M48ALMTHDDOWN Lower limit of No.2 input -48V[-V]
NO2M48ALMTHDUP Upper limit of No.2 input -48V[-V]
NO3M48ALMTHDDOWN Lower limit of No.3 input -48V[-V]
NO3M48ALMTHDUP Upper limit of No.3 input -48V[-V]
NO4M48ALMTHDDOWN Lower limit of No.4 input -48V[-V]
NO4M48ALMTHDUP Upper limit of No.4 input -48V[-V]
NO5M48ALMTHDDOWN Lower limit of No.5 input -48V[-V]
NO5M48ALMTHDUP Upper limit of No.5 input -48V[-V]
NO6M48ALMTHDDOWN Lower limit of No.6 input -48V[-V]
NO6M48ALMTHDUP Upper limit of No.6 input -48V[-V]
NOAMRFULLTOHALFHOALLOW Non-AMR F-H Ho Allowed
NOAMRFULLTOHALFHOATCBADJSTEP Non-AMR F-H Ho ATCB Adjust Step
NOAMRFULLTOHALFHOATCBTHRESH Non-AMR F-H Ho ATCB Threshold
NOAMRFULLTOHALFHOPATHADJSTEP Non-AMR F-H Ho Pathloss Adjust Step
NOAMRFULLTOHALFHOPATHTHRESH Non-AMR F-H Ho Pathloss Threshold
NOAMRFULLTOHALFHOQUALTHRESH Non-AMR F-H Ho Qual. Threshold
NOAMRFULLTOHALFTHRESH Non-AMR F-H Traffic Threshold
NOAMRHALFTOFULLHOATCBTHRESH Non-AMR H-F Ho ATCB Threshold
NOAMRHALFTOFULLHOPATHTHRESH Non-AMR H-F Ho Pathloss Threshold
NOAMRHALFTOFULLHOQUALALLOW Allow Non-AMR H-F Quality-based HO
NOAMRHALFTOFULLHOQUALTHRESH Non-AMR H-F Ho Qual. Threshold
NOAMRHALFTOFULLTHRESH Non-AMR H-F Traffic Threshold
NODET Adjacent Node Type
NODLMRHOALLOWLIMIT Cons.No Dl Mr.HO Allowed Limit
NODLMRHOEN No Dl Mr.HO Allowed
NODLMRHOQUALLIMIT No Dl Mr.Ul Qual HO Limit
NOMINALCAPACITY Norminal Capacity{AH}
NONAMRCALLPCALLOWED Allow III Power Control For Non-AMR
NONDRXPERIOD Non-DRX Period
NormalCurDurA A ALD Cur-Minor Alarm N-Cur Duration
NormalCurDurB B ALD Cur-Minor Alarm N-Cur Duration
NORMALRESELALLOW Cell Normal Reselection Allowed
NORTHD Normal Work TEMP Threshold
NOTMSIALLCELLPAGINGLIMITFLAG Discard TMSI All Cell Paging
NOTRASP Statistical Period of No-traffic
NOVGCSTIME No VGCS Call Time
NQUERIES Number of TRACERT Packages Per TTL
NRBSDCCHFFLEN Filter Length for SDCCH NBR_RCVD_BLOCK
NRBTCHFFLEN Filter Length for TCH NBR_RCVD_BLOCK
NRI NRI Value
NRI NRI Value
NRofFDDCellFlag Support NR_of_FDD_cells Writing
NSEI NSE Identifier
NSEI NSE Identifier
NSIGSTRFLTLEN NCell Filter Length for SDCCH Level
NSLATI NS Latitude
NSVCI NSVC Identifier
NSVCIDX NSVC Index
NTDI Normal Temperature Delta Tin
NTDO Normal Temperature Delta Tout
NY2 Ny2
OAMFLOWBW OAM flow min bandwidth[%]
OAMFLOWBW OAM flow min bandwidth[%]
OAMFLOWBW OAM flow min bandwidth[%]
OAMFLOWBW OAM flow min bandwidth[%]
OAMFLOWBW OAM flow min bandwidth[%]
OAMFLOWDSCP DSCP of OAM flow
OAMMINBWKEY OAM flow min bandwidth switch
OBJECTTYPE Operate Object
OBJECTTYPE Object Type
OBJIDX User Index
OBJIDX Object Index
OBJTP Object Type
OBJTP Object Type
OBJTYPE Object Type
OccupyStreamingSwitch Preempt Switch of Streaming Resource
OLTOULHOALLOW OL to UL HO Allowed
OMLBKUP Configure Backup OML
OMLDETECTSWITCH OML Detection Switch
OmlDetectTime OML Lapd Link Detect Time
OMLDSCP OML DSCP
OMLESLDL BTS OML&ESL Average Down-bandwidth
OMLESLUL BTS OML&ESL Average Up-bandwidth
OMLPRI OML Priority
OMLSP OML Service PRI
OMLVLANID OML VlanId
OMLWS OML/ESL/EML LAPD Downlink Window Size
OMUIP OMU External Network Virtual IP
OMUMASK OMU External Network Mask
OP Operator
OPC OSP Code
OPC OSP Code
OPCIDX OPC Index
OperatorType Operator Type
OPINDEX Operator Index
OPINDEXSET OP INDEX SET
OPMODE Operate mode
OPMODE Operation Mode
OPMODE Operation Mode
OPMODE Operation Mode
OPMODE Operation Mode
OPNAME Operator Name
OPTILAYER Assign Optimum Layer
OPTILEVTHRES Assign-optimum-level Threshold
OPTITATHRES TA Threshold of Assignment Pref
OPTL TRX Priority
OPTM Optical interface standard
OPTP Operation Type
OPTYPE Operate Type
OPX OPX
ORIPORT Originally E1/T1 Port No.
OT Operation type
OTHERFREQ Other Frequency
OTHMODNUM Number of Other-RAT Modules
OTOURECEIVETH OtoU HO Received Level Threshold
OUTASSOPTEN UL Subcell Assignment Optimization
OUTBSCHOCLEARTIMER T8
OUTBSCHOCMDTIMER T7
OutBscLoadHoEn Inter BSC Load Information Allowed
OUTGENOVERLDTHRED UL Subcell General Overload Threshold
OUTHOPWROVERLOADTHRESHOLD Power Overload Threshold In Ho. Out
OUTINNREXLEVTHRED Outgoing OL Subcell HO Level TH
OUTLOADHOENABLE Load HO Allowed
OUTLOADHOMODPERI MOD Step LEN of UL Load HO Period
OUTLOADHOPERIOD UL Subcell Load Hierarchical HO Periods
OUTLOADHOSTEP Step Length of UL Subcell Load HO
OUTLOWLOADTHRED UL Subcell Lower Load Threshold
OUTMASK Out BSC Mask
OUTPN Out BSC Port No.
OUTPORTNO DXX Out Port No.
OUTPORTTS DXX Out Time Slot No.
OUTPUT0 Cannel 0 Digital Control Signal Level
OUTPUT1 Cannel 1 Digital Control Signal Level
OUTPUT2 Cannel 2 Digital Control Signal Level
OUTPUT3 Cannel 3 Digital Control Signal Level
OUTPUTPOWER Output Power
OUTPUTPOWER1 Output Power
OUTPUTPOWERUNIT Output Power Unit
OUTSERIOVERLDTHRED UL Subcell Serious Overload Threshold
OUTSERVICEALM Cell Out-of-Service Alarm Switch
OUTSN Out BSC Slot No.
OUTSN Load Outlet Slot No.
OUTSRN Out BSC Subrack No.
OutSysLoadHoEn Allow Inter-RAT Load HO in Connect State
OUTSYSSERVHOREASSIGNEN Service Handover Reassign
OUTSYSSERVICEHOEN Service Based Handover Switch
OUTTIMER Load Info Timeout Timer
OUTTSN Out BSC Start Timeslot No.
OverCurAlmThdA ANT_A ALD Over Current Occur Threshold
OverCurAlmThdB ANT_B ALD Over Current Occur Threshold
OverCurAlmThdRET RET ALD Over Current Occur Threshold
OverCurClrThdA ANT_A ALD Over Current Clear Threshold
OverCurClrThdB ANT_B ALD Over Current Clear Threshold
OverCurClrThdRET RET ALD Over Current Clear Threshold
OverCurDurA A ALD Cur-Minor Alarm Over-Cur Duration
OverCurDurB B ALD Cur-Minor Alarm Over-Cur Duration
OVERLOADINTV Overload Indication Period
OVERTHD Derating TEMP Threshold
P11 CPU Usage for Critical Paging FC
P12 CPU Usage for Major Paging FC
P13 CPU Usage for Minor Paging FC
P14 CPU Usage for Slight Paging FC
PaAdjVol PA Intelligent Adjust Voltage
PACKASSDLSHIFT Move Packet Assignment Down to BTS
PAGINGAVGCAPACITYINPERIOD Average Paging Message Number In Period
PAGINGLIFETIME BTS Paging Lifetime
PAGINGMAXCAPACITYINPERIOD MAX Paging Message Number In Period
PAGTIMES Paging Times
PANDEC PAN_DEC
PANINC PAN_INC
PANMAX PAN_MAX
PAOPTILEVEL Priority of Shut Down TRX
PatchNo Patch No.
PatchNo1 Patch Number
PATHCHK IP path check flag
PATHID IP path ID
PATHID IP path ID
PATHLOSS Path Loss of Different Frequency Band
PATHLOSSHOEN Pathloss Ho. Enable
PATHT IP path type
PATTYPE Patch type
PB Pb
PBGTHOEN PBGT HO Allowed
PBGTLAST PBGT Valid Time
PBGTMARGIN PBGT HO Threshold
PBGTSTAT PBGT Watch Time
PbMtnMsgReSend MAX Retrans Maintenance Msg on Pb-I
PCADJPERIOD PC Interval
PCMEASCHAN PC_MEAS_CHAN
PCU PCU No
PCUINDEX PCU No.
PCUNO PCU No.
PCUNO PCU No.
PCUPREEMPTFLAG PCU Support PREEMPT_ABIS_LINK Message
PDCHDWNLEV PDCH Downlink Multiplex Threshold
PDCHPWRSAVEN PDCH Power Saving Enable
PDCHREFORMING PDCH Reforming
PDCHUPLEV PDCH Uplink Multiplex Threshold
PDTMRVALUE PENDING timer
PeerBSCID Peer BSC ID
PEERBSCID Peer BSC ID
PEERBSCIP Peer BSC IP
PEERBSCMASK Peer BSC Mask
PEERBTSID Peer BTS ID
PEERIP Peer IP address
PEERIP Peer IP address
PEERIP Peer IP address
PEERIP Peer IP Address
PEERIP Peer IP Address
PEERIP1 First destination IP address
PEERIP2 Second destination IP address
PEERIPADDR Peer IP address
PEERMASK Peer subnet mask
PEERPN Destination SCTP port No.
PEERVERSION Peer Version
PENALTYEN Penalty Allowed
PENALTYLASTTM Cell Penalty Duration
PENALTYRXLEV Cell Penalty Level
PENALTYTIMER CfgPenaltyTimer
PERIOD Ping Check Period
PERIOD Measurement Period
PFC Protocal field compress
PFC Protocol field compress
PFC Support Protocol Field Compress
PFCSUP PFC Support
PGCLASSIFINGALLOWED Paging Message Classifying Allowed
PGMAXMSGNUMINPERIOD Max CS Paging Message Num in Period
PGMAXPSMSGNUMINPERIOD Max PS Paging Message Num in Period
PGSTATPERIOD Paging Statistical Period
PHB Per-Hop Behavior
PHB PHB
PI Cell Reselect Parameters Indication
PKPEnableSta Private Key Password Enabled State
PKTCOUNT PKT Count
PKTLEN PKT Size[Byte]
PKTLEN Packet Length
PKTLENTHRES Maximum Frame Length
PKTSI PACKET SI
PKTSIZE Size of packet
PKTSIZE PKT Size
PL1 Persistence Level 1
PL16QAM 16QAM Transmitter Power Reduce Level
PL2 Persistence Level 2
PL3 Persistence Level 3
PL32QAM 32QAM Transmitter Power Reduce Level
PL4 Persistence Level 4
PL8PSK TRX 8PSK Level
PLPRD Packet lost measure period [100ms]
PLTH Packet discard threshold[0.001]
PLYPOINT Play Point
PLYSWITCH Play Switch
PLYTIME Play Time
PMCTHD Performance monitor control threshold
PMCTHD Performance monitor control threshold
PMI Interval for Sending Cell Paging Package
PMNUM Number of Cell Pagings in One Package
PMOAFLAG Cell Paging Package Switch
PMRTHD Performance monitor restore threshold
PMRTHD Performance monitor restore threshold
PMSW Performance monitoring flow control switch
PN Port No.
PN Port No.
PN Port No.
PN Port No
PN Port No
PN BM Port No
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Physics port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
PN Port No.
POCDELAY Transmission Delay of POC Service
POCGBRMAX Max. GBR for POC Service
POCGBRMIN Min. GBR for POC Service
PocSup POC Support
PODECTHRES Power Output Reduction Threshold
POERRTHRES Power Output Error Threshold
POINTDESINFO Rollback Point Description
POINTNAME Rollback Point Name
Port Destination Port
PORT Port
PORT Port
PORTNO DXX In Port No.
PORTNUM DXX Port Number
PORTPROTYPE Port protocol type
PortSwitch Panel Port Switch
PORTTYPE Port Type
PORTTYPE Port Type
POS2QUATER 2Quater Message Transmission Channel
POT Patch Operation Type
POWER Rated Power
POWER_RELAY1 Switch for Relay 1
POWER_RELAY2 Switch for Relay 2
POWER_RELAY3 Switch for Relay 3
POWER_RELAY4 Switch for Relay 4
POWER_RELAY5 Switch for Relay 5
POWER_RELAY6 Switch for Relay 6
POWERCURRENTDIV Battery Shunt Coefficient
POWERREDUCE16QAM 16QAM Transmitter Power Reduce Level
POWERREDUCE32QAM 32QAM Transmitter Power Reduce Level
POWERTYPE Power Type
POWERTYPE Cabinet Power System Type
POWL Power Level
POWT Power Type
PPPEAAT PPP Frame Error Alarm Threshold
PPPEADT PPP Frame Error Alarm Clearance Threshold
PPPLNKN PPP link No.
PPPLNKN PPP sub-link No.
PPPLNKN PPP link No.
PPPLNKN PPP Link No.
PPPMUX PPP mux
PQNUM Priority queue number
PREEMFORHONOTREL Preempted Call Not Released After Handover Failure
PDCH Preemption Allowed During Handover Due to
PREEMFORHOPDCH Preemption
PREEMPTIONPERMIT Emergency Call Preemption Permitted
PREMRSAMPLE Preprocess MR Sample Ratio
PRI Route Priority
PRIACCTHR Packet Access Priority
PRIFCEN Support Priority Based Flow Control
PRIMMESPPT Transfer Original MR
PRINTCTHD Print control threshold
PRINTCTHD Print control threshold
PRINTRTHD Print restore threshold
PRINTRTHD Print restore threshold
PRINTSW Print Flow control switch
PRIOR Cell Priority
PRIOR Cell Priority
PRIORABISLOADTHRED Flex Abis Prior Choose Load Thred
PRIORCLASS Cell HCS Prior Class
PRIORITY Route priority
PRIORITY Signalling link priority
PRIORITY Priority
PRIVATEPROBEFST Preferential Customized Detection Type
PRIVATEPROBENUM Number of Customized Detection Types
PRIVATEPROBESND Subsidiary Customized Detection Type
PrivKey Private Key File Name
PROBESEQ BTS Port Detection Sequence
PROT SS7 protocol type
PROT Frame Relay Protocol Type
PROTECTDELAYTIME Protection Delay for Detection
PROTECTTIME Dyn. Turning Off Cell Protection Time
ProtectTimeTrxPowerOn TRX Power-on Protection Time
PS Port select
PS Port select
PS Port select
PSCHRABIS PS CHR Abis
PSCHRGB PS CHR Gb
PSCHRINNINFO PS CHR Inner Information
PSCHRINNMSG PS CHR Inner Message
PSCHRUM PS CHR Um
PSDATADL GSM PS data service downlink factor
PSDATAUL GSM PS data service uplink factor
PSHOSUP PS Handover Support
PSHPRIDATAPATH PS high PRI data path
PSHPRIDATAPRI PS high PRI data priority
PSHPSP PS High PRI Service PRI
PSI1RPT PSI1 Repetition Period
PSISTATUSIND Support PSI Status Message
PSLPRIDATAPATH PS low PRI data path
PSLPRIDATAPRI PS low PRI data priority
PSLPSVP PS Low PRI Service PRI
PSOTOURECEIVETHRSH PS OtoU HO Receive Level Threshold
PSOUTMODE Mode Control
PSRACHACCLEV PS RACH Min. Access Level
PSRACJACCLEV PS Min.Access Level
PSRCDSW PS CHR Switch
PSRESREQMSGNUMINPERIOD Max PS Resource REQ Num in Period
PSRESREQSTATPERIOD PS Resource REQ Statistical Period
PSU0 DPSU 0 Configured
PSU1 DPSU 1 Configured
PSU2 DPSU 2 Configured
PSU2 DPSU 2 Configured
PSU3 DPSU 3 Configured
PSU4 DPSU 4 Configured
PSU5 DPSU 5 Configured
PSU6 DPSU 6 Configured
PSU7 DPSU 7 Configured
PSUTOORECEIVETHRSH PS UtoO HO Receive Level Threshold
PSUTURNINGOFFENABLE PSU Turning Off Enable
PSW Self-healing Switch for OMU Process
PT Port Type
PT Port
PT Cell Reselect Penalty Time
PT Subnet Protocol Type
PT Port Type
PTCODE Line code
PTRXT Frame receive Structure
PTTXT Frame send Structure
PTTYPE Frame Structure
PTUID HDLC Path Index In BTS
PTYPE Port type
PTYPE Power System Type
PubCert Certificate File Name
PV BTS Patch Version
PV Patch Version
PVCUSERATETIMER PVC Utilization Report Period Timer
PWD Private Key Password
PWD Password
PWD User Password
PwdMinLen Minimum Password Length
PWL Power Level
PWRALMSSW1 First Alarm Switch
PWRALMSSW2 Second Alarm Switch
PWRBCDALLOWD Power Forecast Allowed
PWRCTRLOPTIMIZEDEN III Power Control Optimized Enable
PWRCTRLSW Power Control Switch
PWRDIV Power Deviation
PWRDIVIND Power Deviation Indication
PWRLOCATION Location Group Power Switch
PWRMODE Power Class
PWROFFPROTECTSTARTTIME Power-off Protect Start Time
PWRPRIORALLOW Power Priority Allowed
PWRSPNR Power Finetune
PwrSwitchA ANT_A ALD Power Switch
PwrSwitchB ANT_B ALD Power Switch
PwrSwitchRET RET ALD Power Switch
Q0MINDSCP Min DSCP of queue 0
Q1MINDSCP Min DSCP of queue 1
Q2MINDSCP Min DSCP of queue 2
Q3MINDSCP Min DSCP of queue 3
Q4MINDSCP Min DSCP of queue 4
QCI Qsearch C Initial
QCKMVHOEN MS Fast Moving HO Allowed
QCKSTATCNT MS Fast-moving Watch Cells
QCKTIMETH MS Fast-moving Time Threshold
QCKTRUECNT MS Fast-moving Valid Cells
QI Qsearch I
QLENSD Filter Length for TCH Qual.
QLENSI Filter Length for SDCCH Qual.
QOSOPT Support QoS Optimize
QP Qsearch P
QSEARCHC Qsearch C
QTRUCHANMANGSWITCH QTRU Signal Merge Avoid Switch
QTRUDNPWRLASTTIME Qtru Down Power Inadequate Last Time
QTRUDNPWRSTATTIME Qtru Down Power Inadequate Stat Time
QTRUPWRSHARE Multi-Density TRX Power Sharing
QUALOFFTIMES Qualified Times for Off
QUALONTIMES Qualified Times for On
QUALSTEP MAX Down Adj. PC Value by Qual.
QUERYCMAFTERINBSCHO Query Classmark after In-BSC HO Enabled
QUICKHOEN Quick Handover Enable
R0AuxDev SubRack0 Auxiliary Equipment
R0BatAllow SubRack0 Storage Battery Config Permit
R0BatCap SubRack0 Storage Battery Capacity
R0BatCoeff SubRack0 Storage Battery Coefficient
R0BatType SubRack0 Storage Battery Type
R1AuxDev SubRack1 Auxiliary Equipment
R1BatAllow SubRack1 Storage Battery Config Permit
R1BatCap SubRack1 Storage Battery Capacity
R1BatCoeff SubRack1 Storage Battery Coefficient
R1BatType SubRack1 Storage Battery Type
R2AuxDev SubRack2 Auxiliary Equipment
R2BatAllow SubRack2 Storage Battery Config Permit
R2BatCap SubRack2 Storage Battery Capacity
R2BatCoeff SubRack2 Storage Battery Coefficient
R2BatType SubRack2 Storage Battery Type
RA RAC
RA Route Area
RA Routing Area
RA Route Area
RA Route Area
RA1 Route Area
RACHACCLEV CS RACH Min. Access Level
RACHBUSYTHRED RACH Busy Threshold
RACHLDAVERSLOT Average RACH Load Timeslot Number
RACJACCLEV CS Min.Access Level
RACOLOR Routing Area Color Code
RANDACCESSRETRY Allow MS to Access to Another Cell
RANERRTHRED Random Access Error Threshold
RARESELECTHYST Accessorial Hysteresis of Cell Selection
RATE Rate
RATECTRLSW AMR Rate Control Switch
RATSCCHENABLED Is RATSCCH Function Enabled
RAWMRSAMPLE Raw MR Sample Ratio
RBPTYPE Type of Rollback Point
RCDT Result Recording Type
RCN Chain No.
RCN1 First RXU Chain No.
RCN2 Second RXU Chain No.
RCVMD Receive Mode
RDC Rate down coefficient [%]
REASSEN Allow Reassign
REASSFREQBAND Frequency Band of Reassign
RECEIVEQUALTHRSHAMRFR ReceiveQualThrshAMRFR
RECEIVEQUALTHRSHAMRHR ReceiveQualThrshAMRHR
RECLEVHYST RX_LEV Hysteresis
RECLEVTHRES RX_LEV Threshold
RECLEVUOHOALLOW RX_LEV for UO HO Allowed
RecordDiscardedPagingInfoFlag Record Discarded Paging Msg
RECOVERTHD Decrease rate alarm recover threshold
RECQUALTH RX_QUAL Threshold
RECQUALUOHOALLOW RX_QUAL for UO HO Allowed
RED Backup
Interval to Reduce Transmission Bandwidth when
ReduceTransBwInt Congested
Number of Transmission Bandwidth to Reduce when
ReduceTransBwNum Congested
REF2MCLK2SRC Port for LINE2
REF2MCLK2SRCBAK Back-up port for LINE2
REF2MCLKSRC Port for LINE1
REF2MCLKSRCBAK Back-up port for LINE1
REF2MCLKSW1 Switch of panel 2M BITS1
REF2MCLKSW2 Switch of panel 2M BITS2
REFUSELOCALCLK Use SGSN clock source
REGION Region Information
REHOSTABSTIME ReHost Absolute Time
REHOSTDELAYTIME ReHostDelayTime
REHOSTTYPE ReHost Type
REINITTBL Reinitialize Neighbour Cell Table
RELATEDCN Associated Board CN
RELATEDFCUENABLED Extend Connection Configuration Enabled
RELATEDMODFUNC Associated Board Function
RELATEDSN Associated Board SN
RELATEDSRN Associated Board SRN
RELATEDTRACK Cascading Tributary
REMARK Remark
REMARK Route use description
REMOTENSVLI Remote NSVL ID
REP Repeat
REPEATDLFASET Repeated Downlink FACCH
REPEATDLFATHRED Repeated Downlink FACCH Threshold
REPEATSASET Repeated SACCH
RESALMID Reserved Alarm ID.
ResCheckAllowed ResCheckAllowed
RESELHYST Cell Reselection Hysteresis
RESELINTERVAL Cell Reselect Interval
RESELWATCHPERIOD Normal Cell Reselection Watch Period
RESELWORSENLEVTHRSH Normal Cell Reselection Worsen Level Threshold
ReservedDynPdchPreTranNum Number of Reserved Dynamic Channel
ReservedIdleCh Reserved TCH Number for PA Turning On
ResetAlmDelaySwitch BTS Reset Alarm Delay Switch
ResetAlmDelayTime BTS Reset Alarm Delay Time
RESETINTERVAL Reset Interval of Account Lock Counter
RESETRETRY Reset Retry
RESETTIME BTS Reset Time
RESETTIMER Reset Timer
RESID Reason
RespReqSel Response on Out-BSC HO Req
REST Resume Broken Downloads Flag
RESTARTTMR Sub-protocol negotiate out time[S]
RESTARTTMR Sub-protocol negotiate out time[S]
RESTYPE Alarm Restore Type
RESUMETIMER Resume Timer
REVCHANNUM Reserved Channel Number
RFMAXPWRDEC Max RC Power Reduction
RFRESINDPRD Radio Resource Report Period
RFT Execute Interval
RFUCFGBYSLOT Configure RFU by Slot
RGPSINDICATION GPS or RGPS
RIMSUP RIM Support
RLCN Channel No.
RLT Radio Link Timeout
RMTTCATERTRANSMODE Remote TC Subrack Ater Transmission Mode
RNCID RNC ID
RNCINDEX Neighboring RNC Index
RNCINDEX Neighboring RNC Index
RNCNAME Neighboring RNC Name
RootCert Root Certificate File Name
ROUTENO Route No.
ROUTEPORTNO Route Port No.
RPTDLVQIALLOWED Report Downlink VQI Allowed
RPTPERIODI Cell Reselection MR Period in Packet Idle Mode
RPTPERIODT Cell Reselection MR Period in Packet Transfer Mode
RPTTHD Decrease rate alarm report threshold
RPTVOICE Report Speech Quality
RQSIGNLEN Filter Length for SDCCH REP_QUANT
RQTRAFFLEN Filter Length for TCH REP_QUANT
RSCGRPN Rscgrp No.
RSCMNGMODE Resource Management Mode
RSCMNGMODE Resource management mode
RSCPENALTYTIMER RscPenaltyTimer
RSCPOFF RSCP Offset
RSCPTHRES RSCP Threshold for Layer of 3G Cell
RSDSRC RSD alarm source
RSFSRC RSF alarm source
RSLCTOFFER GPRS Reselection Offset
RSLDL BTS RSL Average Down-bandwidth
RSLDSCP RSL DSCP
RSLPRI RSL Priority
RSLUL BTS RSL Average Up-bandwidth
RSLVLANID RSL VlanId
RSLWS RSL LAPD Window Size
RSNDES Lock Reason
RSSThres Relative Signal Strength Threshold
RSTDESFILE Reset file
RSTF Result File Name
RSTFUN Restart switch
RSTIME Restart Timer
RSVCHMFORECNUM Max Channel Num Reserved for EC
RSVDPARA1 Reserved Parameter 1
RSVDPARA10 Reserved Parameter 10
RSVDPARA2 Reserved Parameter 2
RSVDPARA3 Reserved Parameter 3
RSVDPARA4 Reserved Parameter 4
RSVDPARA5 Reserved Parameter 5
RSVDPARA6 Reserved Parameter 6
RSVDPARA7 Reserved Parameter 7
RSVDPARA8 Reserved Parameter 8
RSVDPARA9 Reserved Parameter 9
RsvIdleChanNum Reserve Idle Channel Number
RT Revertive type
RTCONTEXT Routing Context
RTCPBWRATIO RTCP Bandwidth Usage
RTCPSWITCH Enable RTCP
RTDEST Destination Network Address
RTDESTMASK Destination Address Mask
RTIDX Route Index
RTOALPHA RTO alpha value
RTOBETA RTO beta value
RTOINIT RTO initial value
RTOMAX RTO max value
RTOMIN RTO min value
RTPSWITCH Measure Link Delay Switch
RTTIPDCHMULTIPLEXTHRESH RTTI PDCH Multiplex Threshold
RTTYPE Route Type
RUS Rate up step [kbps]
RUSPRD Rate up step adjust period [PLPRD]
RVer R-Version No.
RXBW Backward Bandwidth
RxBw Backward Bandwidth
RXLEVACCMIN Minimum Receiving level for Access
RXLEVOFF Interfere HO Qual. Thresh Offset for AMR FR
RXMIN Minum Access RXLEV
RXQCKFALLHOEN Rx_Level_Drop HO Allowed
RXQUAL1 Interfere HO Qual. Thresh 1 for Non-AMR FR
RXQUAL10 Interfere HO Qual. Thresh 10 for Non-AMR FR
RXQUAL11 Interfere HO Qual. Thresh 11 for Non-AMR FR
RXQUAL12 Interfere HO Qual. Thresh 12 for Non-AMR FR
RXQUAL2 Interfere HO Qual. Thresh 2 for Non-AMR FR
RXQUAL3 Interfere HO Qual. Thresh 3 for Non-AMR FR
RXQUAL4 Interfere HO Qual. Thresh 4 for Non-AMR FR
RXQUAL5 Interfere HO Qual. Thresh 5 for Non-AMR FR
RXQUAL6 Interfere HO Qual. Thresh 6 for Non-AMR FR
RXQUAL7 Interfere HO Qual. Thresh 7 for Non-AMR FR
RXQUAL8 Interfere HO Qual. Thresh 8 for Non-AMR FR
RXQUAL9 Interfere HO Qual. Thresh 9 for Non-AMR FR
RXUCHAINNO RXU Chain No
RXUCHAINNO RXU Chain No.
RXUCHAINNO RXU Chain No.
RXUIDTYPE RXU Index Type
RXUIDTYPE RXU Index Type
RXUNAME RXU Name
RXUNAME RXU Name
RXUNAME RXU Name
RXUPOS RXU Chain Position
RXUPOS RXU Chain Position
RXUPOS RXU Board Position
RXUTYPE RXU Board Type
S1SWITCH S1 value setting switch
S1VALUE S1 Value
SAADIS Special Analog Alarm Enabled
SAAF Special Analog Alarm Flag
SaGsmrMsc Trunking MSC
SAICALLOWED SAIC Allowed
SAICTHREDAPDTVALUE Power Control Threshold Adjust for SAIC
SAICTHREDAPDTVALUE Power Control threshold Adjust for SAIC
SALOG Special Analog Alarm Enabled
SAMECVGCELLID Same Coverage Cell No
SAMECVGCELLIDTYPE Same Coverage Cell Index Type
SAMECVGCELLLOADSTATTM Same Coverage Cell Load Stat. Time
SAMECVGCELLLOADTHRD Same Coverage Cell Load Threshold
SAMECVGCELLNAME Same Coverage Cell Name
SAMULFRM SACCH Multi-Frames
SAS Special Alarm Switcher
SASE Special Alarm Switch Enabled
SASV Special Alarm Switch Valid Vol. Level
SAVEENABLED Energy Saving Support
SBAF Special Bool Alarm Flag
SBTSID First BTS Index
SBTSNAME First BTS Name
SCALEORDER SCALE_ORDER
SCDSCP DSCP of STREAM[QoS]
SCELLFILTER Serving Cell Filter Length MR Number
SCELLID First Cell Index
SCELLNAME First Cell Name
SCHEME Coding Scheme
SCHNNO Sub Channel No.
SCMD Command String
SCOPETYPE Scope Type
SCPIDX Subrack Communication Path Index
SCRAMBLE Scrambling Code or Cell Parameter Id
SCSN Start Serial No.
SCTPLNKN SCTP link No.
SD Start Date
SD Start Date
SD Start Date
SD Alarm Log Saved Time
SDALMTHD SD Alarm Threshold
SDATE Start Date
SDAY Start date
SDCCHNUM SDCCHChannelNumber
SDCCHWaitMREn Waiting for MR on SDCCH Switch
SDCCHWaitMRTimeLen Duration for Waiting MR on SDCCH
SDDROPSTATDLLEV DL Level Threshold for SDCCH Call Drop
SDDROPSTATDLQUAL DL Quality Threshold for SDCCH Call Drop
SDDROPSTATULLEV UL Level Threshold for SDCCH Call Drop
SDDROPSTATULQUAL UL Quality Threshold for SDCCH Call Drop
SDDYN SDCCH Dynamic Allocation Allowed
SDENABLE SD Enable
SDFASTHOSWITCH SD Quick HO
SDFLAG Shut Down Enabled
SDHOMININTV Min Interval for SDCCH Hos
SDMRCUTNUM SdMrCutNum
SDPUNTIME Penalty Time on Fast Moving HO
SDPUNVAL Penalty on Fast Moving HO
SDSCP DSCP of Signaling
SDSFPRI SDSF Priority
SDT Shutdown Temperature
SDTMWDALMDIS Sliding Time Window Alarm Disappear
SDTMWDALMOC Sliding Time Window Alarm Occurrence
SDV Shutdown Voltage
SEARCH3G 3G Search PRIO
SELFVERSION Self Version
Send2QuterFlag Support Sent 2QUATER
SendBssInvokeTrace Spt BSS Invoke Trace Rpt[end2end user trace]
SENDCMAFTERINBSCHO Send Classmark ENQ Result to MSC Enabled
SendConfusionToMSC Sent Confusion Message to MSC
SENDDOWNLINKMESSAGE Send Downlink Message after Hanging up
SENDFACCHNOTPRI Send FACCH Notification Priority
SENDFACCHPAGPRI Send FACCH Paging Priority
SENDSAMBE BSC Auto Link Flag
SENDSI2TERFLAG Send System Information 2ter
SENDSI5TERFLAG Send System Information 5ter
SendUtranECSCFlag Send 3G Class Flag
SEPARATEPOS Separate Position
SEPERATEMODE Separate Mode
SERCMDPORT The Command Port of FTP Server
SERDATAPORT The Source Date Port of FTP Server
SERIALNO Device Serial No.
ServerIP FTP Server IP Address
ServiceMode Service mode
SERVICEMODE Service Type
SERVICEMODE Service Type
ServiceName Service Name
SERVICETYPE Service Type
SETDIESELENGINEENABLED Diesel Engine Configure Enabled
SETENVPARAENABLED ENV TEMP CFG Enabled
SETENVPARAENABLED ENV TEMP CFG Enabled
SETHUMPARAENABLED Environment Humidity Configure Enabled
SFPPORTNO SFP Port No
SGSNCAP Configure Capacity<K User Number>
SGSNNAME SGSN Name
SGSNNRILEN SGSN NRI Length
SGSNNULLNRI SGSN NullNRI Value
SGSNPOOLALLOW Allow SGSN Pool
SGSNR Protocol Version Supported by SGSN
SGSNSTATUS SGSN Management Status
SHAREINCPURATE Share in CPU Rate
SHARESN Load Sharing Slot No.
SHARINGALLOW Sharing Allow
SHLDFLG Shield Flag
SHUTDOWNTRXSTARTTIME Shutdown TRX Start Time[T2]
SI2TerSwitch SI 2ter Switch
SIGCHANHOEN SDCCH HO Allowed
SIGLAST Signal Strength Duration Times
SIGLKSX Signalling link set index
SIGLKSX Signalling link set index
SIGLNKID Signaling link ID
SIGLW Signaling Load Weight
SIGLW Signaling Load Weight
SIGNALSP Signal Service PRI
SIGOBS Signal Strength Observation Times
SIGQUAFLTLEN Filter Length for SDCCH Qual
SIGSLC Signalling link code
SIGSTRFLTLEN Filter Length for SDCCH Level
SilenceTicksOfResReq Interval Between Resource Request
SinglePassExcludeMsisdn1 Single Pass Exclude MSISDN Number 1
SinglePassExcludeMsisdn10 Single Pass Exclude MSISDN Number 10
SinglePassExcludeMsisdn11 Single Pass Exclude MSISDN Number 11
SinglePassExcludeMsisdn12 Single Pass Exclude MSISDN Number 12
SinglePassExcludeMsisdn13 Single Pass Exclude MSISDN Number 13
SinglePassExcludeMsisdn14 Single Pass Exclude MSISDN Number 14
SinglePassExcludeMsisdn15 Single Pass Exclude MSISDN Number 15
SinglePassExcludeMsisdn16 Single Pass Exclude MSISDN Number 16
SinglePassExcludeMsisdn17 Single Pass Exclude MSISDN Number 17
SinglePassExcludeMsisdn18 Single Pass Exclude MSISDN Number 18
SinglePassExcludeMsisdn19 Single Pass Exclude MSISDN Number 19
SinglePassExcludeMsisdn2 Single Pass Exclude MSISDN Number 2
SinglePassExcludeMsisdn20 Single Pass Exclude MSISDN Number 20
SinglePassExcludeMsisdn3 Single Pass Exclude MSISDN Number 3
SinglePassExcludeMsisdn4 Single Pass Exclude MSISDN Number 4
SinglePassExcludeMsisdn5 Single Pass Exclude MSISDN Number 5
SinglePassExcludeMsisdn6 Single Pass Exclude MSISDN Number 6
SinglePassExcludeMsisdn7 Single Pass Exclude MSISDN Number 7
SinglePassExcludeMsisdn8 Single Pass Exclude MSISDN Number 8
SinglePassExcludeMsisdn9 Single Pass Exclude MSISDN Number 9
SIPADDR Source IP address
SIPADDR Source IP address
SITES Sites
SITESYNCZONE Site Sync Zone
SLAVEIPADDR Clock Server IP Address 2
SLAVELOCGRPNO Sub-Location Group No.
SLPTYPE Self Loop Type
SLSMASK Signalling route mask
SLVSERVACTDELAY Slave Service Active Delay
SM StartType
SMLCIDX SMLC Index
SMLCMode SMLC Mode
SMOKE_MASK Enable Smoke Alarm Reporting
SMONTH Start month
SMWINDOW Filter window
SN Slot No.
SN Slot No.
SN Slot No.
SN Slot No.
SN Slot No
SN BM Slot No
SN Slot No.
SN Slot No.
SN Slot No.
SN Slot No.
SN Main Board Logic slot No.
SN Slot No.
SN Slot No.
SN Slot No.
SN Slot No.
SN Slot No.
SN Slot No.
SN Port Slot No.
SN Slot No.
SN Slot No.
SNDMD Send Mode
SndRcvMode DRRU Sending Receiving Mode
SndRcvMode1 DRFU Sending Receiving Mode
SndRcvMode2 MRRU/GRRU Sending Receiving Mode
SndRcvMode3 MRFU/GRFU Sending Receiving Mode
SndRcvMode4 BTS3900E Sending Receiving Mode
SP Sync Period
SPC OSP code[Whole Number]
SPCBITS OSP code bits
SPCDNF OSP code[Divided Number]
SPCIC Start PCIC
SPDF Signal point data format
SPECACC Special Access Control Class
SPECIALSWITCH Special Alarm Switch
SPECIALSWITCHERLEVEL Special Alarm Valid Level Configuration
SpeechAlmPeriod One-Way Mute Alarm Reporting Period
SpeechVerInAssCmp Speech VER Send Flag in ASS CMP
SpeechVerinHoPerform Speech VER Send Flag in HO Perform
SpeechVerInHoReqAck SpeechVerSend Flag in HO REQ ACK
SpeechVerInHoRqd HO_RQD Speech VER
SPEECHVERMODE1 Speech Version Mode 1
SPEECHVERMODE2 Speech Version Mode 2
SPEECHVERSION Speech Version
SPEED ETHPORT SPEED
SPEEDPUNISH Penalty on MS Fast Moving HO
SPEEDPUNISHT Penalty Time on Fast Moving HO
SPGCCCCHSUP Support SPLIT_PG_CYCLE on CCCH
SpprtCB Support Cell Broadcast
SPTCOMMMEAS Allow Common Measurement at Iur-g
SPTINFOEXCHG Allow Info Exchange at Iur-g
SPTINTERRATINBSCPSHO Support In Inter-RAT Inter-cell PS Handover
SPTINTERRATOUTBSCPSHO Support Out Inter-RAT Inter-Cell PS Handover
SPTNACCResGuarantee Support NACC Resource Guarantee
SptPaging Support Paging Message from Trunking MSC
SptPbLapdCheck Support Pb Lapd Check
SptPbResCheck Support Pb Resource Check
SptPbSglPassCheck Support Pb Single Pass Check
SptPCICCheck Support PCIC Check
SptRanSharing Support RAN Sharing
SPTREDUCELATENCY Support Reduced Latency Capability
SPTSHARING RanSharing Support
SPTSTATEFWL Support State Firewall
SPX OSP index
SRANMODE Is Support Normalized Data Configuration
SRANMODE Is Support SingleRAN Mode
SRANMODE Is Support SingleRAN Mode
SRC2GNCELLID Source Cell Index
SRC2GNCELLNAME Source Cell Name
SRC3GNCELLID Source Cell Index
SRC3GNCELLNAME Source Cell Name
SRCCI Source Cell CI
SRCF Source File Name
SRCGRD Clock source priority
SRCGRD Clock source priority
SRCHOCTRLSWITCH Current HO CTRL Algorithm in Source Cell
SRCIP Source IP Address
SRCLAC Source Cell LAC
SRCMCC Source Cell MCC
SRCMEPID MEP ID
SRCMNC Source Cell MNC
SRCPORTNO Source port No.
SRCT Clock source type
SRCTSMASK Source timeslot mask
SRN Subrack No.
SRN Subrack No.
SRN Subrack No.
SRN Subrack No.
SRN Subrack No.
SRN BM Subrack No
SRN Subrack No
SRN Subrack No.
SRN Subrack No.
SRN Subrack No.
SRN Subrack No.
SRN Subrack No.
SRN Subrack No.
SRN Subrack No.
SRN Subrack No.
SRN Port Subrack No.
SRN Subrack No.
SRN Subrack No.
SRN1 Subrack 1 No
SRN2 Subrack 2 No
SRName Subrack name
SRNO Tributary No.
SRT Subrack type
SRTORD Sort Order
SRVLW User Data Load Weight
SRVLW User Data Load Weight
SRVPRIPOLICY Service Priority Policy
SRVTYPE Service Type
SSBQPUNISH Penalty Level after BQ HO
SSCPUAVEUSAGEALMTHD CPU occupancy alarm clearance threshold
SSCPUMAXUSAGEALMTHD CPU occupancy alarm threshold
SSDSPAVEUSAGEALMTHD DSP occupancy alarm clearance threshold
SSDSPMAXUSAGEALMTHD DSP occupancy alarm threshold
SSLENSD Filter Length for TCH Level
SSLENSI Filter Length for SDCCH Level
SSN Subsystem No.
SSN Subsystem No.
SSSN Start Sync Serial No.
SSTAPUNISH Penalty Level after TA HO
ST StartTime
ST Start Time
ST Start Time
ST Start Time
ST Start Time
ST Start Time
ST Start Time
STARTAID Start Alarm ID
STARTCBSHORTMSGFLOWCTRL Prefer Variable Bitmap Code
STARTCHREQARRIVALCTRL CHAN REQ Arrival Control
STARTCIC Start CIC
STARTCIC Start CIC
StartDayDSTPA Prohibit Power Saving Start Day
STARTHEATTEMP Heater Startup Temperature
StartMonthDSTPA Prohibit Power Saving Start Month
STARTPGARRIVALCTRL Paging Arrival Control
STARTPSRESREQARRIVALCTRL PS Resource REQ Arrival Control
STARTSUBTS Start Sub Timeslot No.
STARTTIME Fallback Start Time
StartTimeTACloseTrxPA Time When the Function Is Enabled
STARTTS Start TS
STARTTS Start TS
STARTTS Start Timeslot No.
STC Smart Temperature Control
STC Smart Temperature Control
STCIC Start CIC
STCN Out Port Cabinet No.
STD Start Date
STEP Measurement Step
STFLG Satellite flag
STIME Start Time
STIRCALLOWED EICC Allowed
STOPSI5SWITCH Stop Send SI 5/5bis/5ter after Encrypt
STOPTIME Fallback Stop Time
STP STP function switch
STPN Out-BTS Port No.
STRTM Start Time
STSN Out Port Slot No.
STSRN Out Port Subrack No.
STSUBTS Out-BTS Sub Timeslot No.
STT Start Time
STTS Out-BTS Timeslot No.
STTYPE BTS Type
SUBBSCTID ID of slave BSC in TC Pool
SUBBSCTID ID of slave BSC in TC Pool
SUBCMD Command Parameter
SUBFRAMELEN Max subframe length[byte]
SUBFRAMETHRES Max Subframe Length
SUBID Subtask ID
SUBNET Subnet No
SUBRESPREEMPTFLG Sublink Resources Preemption Switch
SUBRESPREEMPTFLG Sub Res Preempt Flag
SUBTS Sub Timeslot No.
SubVer Sub-Version No.of TMU
SupportApplyUsedCic Support Apply Used A Cic
SUPPORTBAKCLK2SRC Use Back-up port for LINE2
SUPPORTBAKCLKSRC Use Back-up port for LINE1
SUPPORTCELLBROADCAST Support Cell Broadcast Name
SUPPORTDL5TS Support High Multislot Class
SUPPORTDTM Support DTM
SUPPORTEDA Support EDA
SUPPORTENDTM Support Enhanced DTM
SupportIpSpanBtsLSwitch Support FE/GE SPAN BTS Local Switch
SupportTFOCodecOptimize Support TFO Codec Optimize
SupptCellList SupptCellList
SVALUE S Value
SVRIP Server IP
SVRPORT Server UDP Port
SW Switch
SW OMU Automatic Switchover Switch
SW Switch
SW Switch
SW Power Switch
SWEEK Start week
Switch Port switch
SWITCH Self-healing Switch
SWITCH Grace Protection Period Switch
SWITCH Bfd Protocol Switch
SWITCH Alarm Parameter Configuration Enabled
SWITCH3AH 3ah Switch
SWITCHBACKFLAG Switch primary IP address flag
SWITCHBACKHBNUM Switch back HB number
SwitchParameter1 SwitchParameter1
SwitchParameter10 SwitchParameter10
SwitchParameter2 SwitchParameter2
SwitchParameter3 SwitchParameter3
SwitchParameter4 SwitchParameter4
SwitchParameter5 SwitchParameter5
SwitchParameter6 SwitchParameter6
SwitchParameter7 SwitchParameter7
SwitchParameter8 SwitchParameter8
SwitchParameter9 SwitchParameter9
SWITCHPORTNO Switch Port
SWOP Set Enable/Disable
SWSEQ Start week sequence
SYMOFFSET BTS Symbol Offset
SYNCCASE Sync case
SYNCMETHOD Site Synchronization Method
SYNMODE Clock Synchronization Mode
SYNTIMEDAY Days of Inter Sync Period
SYNTIMEHOUR Hours of Inter Sync Period
SYNTIMEMIN Minutes of Inter Sync Period
SYSCONTACT Contact mode of the manufacturer
SYSDESC System description
SYSFLOWLEV System Flux Threshold for Load HO
SYSLOCATION System Location
SysMsg10Allowed Send System Message 10 Allow
SYSOBJECTID NE Name
SYSSERVICES System services
T1 T1
T1 Time1
T10TMR Signalling route set test timer
T12TMR Uninhibit ACK timer
T13TMR Force uninhibit timer
T14TMR Inhibition ACK timer
T17TMR Link realignment timer
T1TMR Time-control changeover timer
T2 T2
T2 Time2
T200 T200
T200FACCHF T200 FACCH/F
T200FACCHH T200 FACCH/H
T200SACCH3 T200 SACCH TCH SAPI3
T200SACCHS T200 SACCH SDCCH
T200SACCT0 T200 SACCH TCH SAPI0
T200SDCCH T200 SDCCH
T200SDCCH3 T200 SDCCH SAPI3
T203 T203
T22TMR Local inhibit test timer
T23TMR Remote inhibit test timer
T2TMR Changeover ACK timer
T3 T3
T3 Time3
T3105 T3105
T3115 T3115
T3168 T3168
T3192 T3192
T3212 T3212
T391 Parameter of DTE [T391]
T3TMR Time-control changeback timer
T4 T4
T4TMR Changeover ACK first attempt timer
T5 T5
T5TMR Changeover ACK second attempt timer
T6 T6
T8 T8
T8TMR Transmission prohibited inhibition timer
TAFLTLEN Filter Length for TA
TAFORUOHOALLOW TA for UO HO Allowed
TAHOEN TA HO Allowed
TAHYST TA Hysteresis
TALASTTIME TA HO Valid Time
TALIMIT TA Threshold
TALKERINFINT Talker Info Interval
TASIGSTRFLTLEN TA Filter Length for SDCCH Level
TASKIDX AISS Task Index
TASTATTIME TA HO Watch Time
TATHRES TA Threshold
TAVGT T_AVG_T
TAVGW T_AVG_W
TB Output Segment No
TB Output Segment No.
TBS Try Switching Duration Time
TBS Ring I Try Rotating Duration Time
TC Test code
TC Tc
TCC Temperature Compensation Coefficient
TCCRCAllowed TC CRC Allowed
TCHAJFLAG TCH Rate Adjust Allow
TCHBUSYTHRES TCH Traffic Busy Threshold
TCHDROPSTATDLFER DL FER Threshold for TCH Call Drop
TCHDROPSTATDLLEV DL Level Threshold for TCH Call Drop
TCHDROPSTATDLQUAL DL Quality Threshold for TCH Call Drop
TCHDROPSTATULFER UL FER Threshold for TCH Call Drop
TCHDROPSTATULLEV UL Level Threshold for TCH Call Drop
TCHDROPSTATULQUAL UL Quality Threshold for TCH Call Drop
TCHHOMININTV Min Interval for TCH Hos
TCHMRCUTNUM TchMrCutNum
TCHRATEMODIFY TCH Rate Modify
TCHTIMEHOPERIOD TCH Time Handover Period
TCHTIMEHOSWITCH TCH Time Handover Switch
TCHTRIBUSYUNDERLAYTHR Tch Traffic Busy Underlay Threshold
TCHTRICBUSYOVERLAYTHR Tch Traffic Busy Overlay Threshold
TCLEN Test code length
TCMODE TC mode
TCMUTEDETECTFLAG Mute Detect Class1 Switch
TCN Tail Cabinet No.
TCPN TC Port No
TCPOOLID TC Pool ID
TCSN TC Slot No
TCSRN TC Subrack No
TCTYPE The type of TC resource
TDDBA1TAG TDD BA1 Input Tag
TDDBA2TAG TDDBA2 Input Tag
TDDCELLOFF TDD Reporting Offset
TDDCELLRESELDIV TDD Cell Reselect Diversity
TDDCELLTHRED TDD Reporting Threshold
TDDDIVERSITY Diversity
TDDDLUARFAN DL UARFAN
TDDMIOPTIMIZEDALLOWED TDD MI System Information Optimized
TDDMIPROHIBIT TDD MI System INFO Broadcasting Prohibit
TDDRSCPQUALTHRSH PS TDD RSCP Quality Threshold
TDDSCRAMBLE Cell Parameter ID
TDDSCRAMBLE Cell Parameter ID
TDDSIOPTIMIZEDALLOWED TDD System Information Optimized Allowed
TDDSYNCCASE Sync Case
TDMCONGCLRTH Congestion clear remain ratio
TDMCONGTH Congestion remain ratio
TDMN1 Subrack 1 TDM Port No
TDMN2 Subrack 2 TDM Port No
TEI TEI
TEMP_MASK Enable Temperature Alarm Reporting
TEMP_THD_HIGH Upper Limit of Temperature Alarm
TEMP_THD_LOW Lower Limit of Temperature Alarm
TEMPALARMTHRESHOLDH Upper ENV TEMP Alarm
TEMPALARMTHRESHOLDH Upper ENV TEMP Alarm
TEMPALARMTHRESHOLDL Lower ENV TEMP Alarm
TEMPALARMTHRESHOLDL Lower ENV TEMP Alarm
TEMPCOMPENSATECOEF Coefficient of Temp Compensation
TEMPLATEDESC Cell Template Description
TEMPLATEID Cell Template Index
TEMPLATEID Cell Template Index
TEMPLATENAME Cell Template Name
TEMPOFHIGHTEMPLOADPWROFF Temp Of High Temp. Load Power Off
TEMPOFLOWTEMPLOADPWROFF Low Temperature Start Load Power Off Temp.
TEMPOFLOWTEMPLOADPWROFF Low Temperature Start Load Poweroff Temp.
TER2INDICATOR TER Indicator of System Information 3
TESTTIMER Test Timer
TEXT Content of Message
TFOOptSwitch TFO Option Switch
TFREQ Test Frequency
TFRMSTARTTIME Frame Start Time
TG Target OMU
TGWID TGW ID
TGWIPOAMIP TGW IP_TRANS IP address
TGWIPOAMMASK TGW IP_TRANS IP Mask
TGWPEERSN TGW TRANS Slot No.
TGWPEERSRN TGW Trans Subrack No.
TH Th
THDOFF Volt Threshold for Off
THDON Volt Threshold for On
THP1ARP1PRIWEIGHT THP1-ARP1 Priority Weight
THP1ARP2PRIWEIGHT THP1-ARP2 Priority Weight
THP1ARP3PRIWEIGHT THP1-ARP3 Priority Weight
THP2ARP1PRIWEIGHT THP2-ARP1 Priority Weight
THP2ARP2PRIWEIGHT THP2-ARP2 Priority Weight
THP2ARP3PRIWEIGHT THP2-ARP3 Priority Weight
THP3ARP1PRIWEIGHT THP3-ARP1 Priority Weight
THP3ARP2PRIWEIGHT THP3-ARP2 Priority Weight
THP3ARP3PRIWEIGHT THP3-ARP3 Priority Weight
THTYPE Threshold type
TI_WAIT_SGSN_PRIVATE_MESSAGE Receive SGSN Config. Msg. Timer
TIGHTBCCHASSMAINBCCHLEV Level Thresh for Assign BCCH Under TBCCH
TIGHTBCCHASSMAINBCCHQUAL Quality Thresh for Assign BCCH Under TBCCH
TIGHTBCCHHOLASTTIME TIGHT BCCH HO Valid Time
TIGHTBCCHHOLOADTHRES Load Threshold for TIGHT BCCH HO
TIGHTBCCHHOSTATTIME TIGHT BCCH HO Watch Time
TIGHTBCCHRXQUALTHRES RX_QUAL Threshold for TIGHT BCCH HO
TIGHTBCCHSWITCH TIGHT BCCH Switch
TIGHTSDCCHRXLEVTHRED IBCA Tight Trx SDCCH Rxlev Threshold
TIIMSIPAGING IMSI Paging Timer
TIME Time Limit
TIME Time
TIME Duration
TIMEAMRFHPUNISH Penalty Time after AMR TCHF-H HO Fail
TIMEBQPUNISH Penalty Time after BQ HO
TIMEOTOUFAILPUN Penalty Time after OtoU HO Fail
TIMEOUT Reply Time-Out[ms]
TIMEOUT Reply Time-Out[ms]
Timeout Time Out
TIMEOUT Time Out
TIMEOUT Maximum Delay Time
TIMEPUNISH Quick Handover Punish Time
TIMES Number of ping packets
TIMESLOTVOLADJALLOW Voltage Adjust Based Timeslots Allowed
TIMETAPUNISH Penalty Time after TA HO
TIMEUTOOFAILPUN Penalty Time after UtoO HO Fail
TIQUEUINGTIMER T11
TIWAITMSCMSG Receive MSC Configuration Message Timer
TL Time Limit
TLLI TLLI
TLT Tout Limit
TLTHD Temperature Alarm Lower Threshold
TLTHD Temperature Alarm Lower Threshold
TM Execute Time
TM1 Execute Time 1
TM2 Execute Time 2
TM3 Execute Time 3
TM4 Execute Time 4
TM5 Execute Time 5
TMI TRMMAP ID
TMIGLD TRMMAP index
TMLEN Time Length
TMODE Test Mode
TMRBADQUALDISCSTAT Timer for Bad Quality DISC Statistic
TMRISTHRD Upper time threshold of raised fault
TMSI TMSI
TMSTLTHRD Lower time threshold of raised fault
TMT1TMR Signalling link test ACK timer
TMT2TMR Signalling link repeat test timer
TNAME Data Table
TNMODE Transmission Mode
TNMODE Transmission Mode
TO AdjustMethod
TO Cell Reselect Temporary Offset
TOPBOARDCN TOP Board Cabinet No.
TOPBOARDSLOTNO TOP Board Slot No.
TOPBOARDSRN TOP Board Subrack No.
TP Log Type
TPN Tail Port No.
TQHO Into-BSC HO REQ Queue Timer
TRACECTHD Debug tracking control threshold
TRACECTHD Debug tracking control threshold
TRACERTHD Debug tracking restore threshold
TRACERTHD Debug tracking restore threshold
TRACESW Debug Flow control switch
TrafficClassDlCoefficient DL Priority Decision Threshold
TrafficClassUlCoefficient UL Priority Decision Threshold
TRAMODE Traffic mode
TransMode Transmission Mode
TRANSSN Load Transmitting Slot No.
TRANST Transport Type
TRANST Transport Type
TRANST Transport Type
TRANSTYPE Carrier Type
TRANSTYPE BTS Transmission Type
TRANSTYPE0 E1 Port 0 Set Optical Transmission Mode
TRANSTYPE1 E1 Port 1 Set Optical Transmission Mode
TRANSTYPE2 E1 Port 2 Set Optical Transmission Mode
TRANSTYPE3 E1 Port 3 Set Optical Transmission Mode
TRCRNGLMT Trace Mode
TRESEL Cell Reselection Forbidden Time
TRIGTHRES Load HO Threshold
TRKLNKPN Trunk Link No.
TRKLNKSN Trunk Link Slot No.
TRKN Trunk No.
TRMI User TRMMAP index
TRMLOADTHINDEX TRM load threshold index
TRMLOADTHINDEX TRM load threshold index
TRMLOADTHINDEX TRM load threshold index
TRMLOADTHINDEX TRM load threshold index
TRMLOADTHINDEX TRM load threshold index
TRMLOADTHINDEX TRM load threshold index
TRMLOADTHINDEX TRM load threshold index
TRMMAPSW Transport Resource Mapping switch
TRUNKN The Trunk group No.
TRUNKN Trunk group No.
TRUNKN Trunk No.
TRXAIDSWITCH TRX Aiding Function Control
TRXDURATS Duration Second
TRXHOPINDEX Channel Hop Index
TRXID TRX ID
TRXID TRX ID
TRXID1 No.1 TRX ID
TRXID10 No.10 TRX ID
TRXID11 No.11 TRX ID
TRXID12 No.12 TRX ID
TRXID13 No.13 TRX ID
TRXID14 No.14 TRX ID
TRXID15 No.15 TRX ID
TRXID16 No.16 TRX ID
TRXID17 No.17 TRX ID
TRXID18 No.18 TRX ID
TRXID19 No.19 TRX ID
TRXID2 No.2 TRX ID
TRXID20 No.20 TRX ID
TRXID21 No.21 TRX ID
TRXID22 No.22 TRX ID
TRXID23 No.23 TRX ID
TRXID24 No.24 TRX ID
TRXID3 No.3 TRX ID
TRXID4 No.4 TRX ID
TRXID5 No.5 TRX ID
TRXID6 No.6 TRX ID
TRXID7 No.7 TRX ID
TRXID8 No.8 TRX ID
TRXID9 No.9 TRX ID
TRXIDLST TRXID LST
TRXIDLST TRX Index List
TRXMAIO Channel MAIO
TRXNO TRX No.
TrxNum TRX Number
TRXPN TRX Board Pass No.
TRXPN Sub-Location Group TRX Board Pass No.
TRXPRIALLOW Allocation TRX Priority Allowed
TRXTP TRX Board Type
TS Time Slot
TS Time Slot
TS time slot No.
TS Bearing Timeslot
TS Time Slot NO.
TSBITMAP Bearing time slot
TSBITMAP Bearing time slot
TSBITMAP Bearing Time Slot
TSC TSC
TSCOUNT Idle TS Count
TSCPLANEN TSC Plan Enable
TSCROSSX Time slot cross index
TSDURAT Duration * 10 minutes
TSIDX Timeslot Index
TSKN Task Name
TSMASK Timeslot Mask
TSMASK TS Mask
TSN Tail Slot No.
TSNO Timeslot No.
TSPRIORITY Timeslot Priority
TSPWRRESERVE Timeslot Power Reserve
TSRAPIDADJPERIOD Fast Flux Measurement TBF Timer
TSRAPIDADJSWITCH Fast Flux Detection Switch
TSRATE Time Slot Rate
TSRN Tail Subrack No.
TSTMODE Test Mode
TSTTIMESLOT Test Timeslot
TSTTYPE Test Type
TSTTYPE Test Type
TsTurningOffEnable Allow Turning Off Time Slot
TT Topo Type
TTL Time to Live
TTL PKT TTL
TURNOFFCELLCHANNUM Dyn. Turning Off Cell Busy Channel Num.
TURNOFFCELLSTPTIME Dyn. Turning Off Cell Stop Time
TURNOFFCELLSTRTIME Dyn. Turning Off Cell Start Time
TURNOFFENABLE Enable Turning Off Cell
TURNONCELLLOADTHRD Dyn. Turning On Cell Load Threshold
TUTHD Temperature Alarm Upper Threshold
TUTHD Temperature Alarm Upper Threshold
TWFCMCHIDLE Observation Cell Channel Reservation Timer
TWFCMTRXIDLE Observation Cell TRX Reservation Timer
TWFCSCHIDLE Serving Cell TCHF Reservation Timer
TWFRRMRSP Information Collection Response Timer
TWFSEEKMS MS Search Timer
TWFSYNCACK BTS Reserved Resource Activation Timer
TWFSYNCRPT BTS SYNC_REPORT Timer
TX TX-integer
TXAOPER1 Assigned Power of Pass A Operators 1
TXAOPER2 Assigned Power of Pass A Operators 2
TXAOPER3 Assigned Power of Pass A Operators 3
TXAOPER4 Assigned Power of Pass A Operators 4
TXBOPER1 Assigned Power of Pass B Operators 1
TXBOPER2 Assigned Power of Pass B Operators 2
TXBOPER3 Assigned Power of Pass B Operators 3
TXBOPER4 Assigned Power of Pass B Operators 4
TXBW Forward Bandwidth
TxBw Forward Bandwidth
TXINT Interval of send[ms]
TXINT TX_INT
TYPE Subrack Type
TYPE Finish Type
TYPE Freq. Band
TYPE PCU Type
TYPE Freq. Band
TYPE Cabinet Type
TYPE Cell Type
U0GEN Up0 Power Attenuation Factor
U0TOW Up0 Tower-Top Amplifier Flag
U0TRX Up0 Link No.
U0TRXBPN Up0 TRX Board Pass No.
U0TRXSN Up0 TRX Slot No.
U0TRXSRN Up0 TRX Subrack No.
U1GEN Up1 Power Attenuation Factor
U1TOW Up1 Tower-Top Amplifier Flag
U1TRX Up1 Link No.
U1TRXBPN Up1 TRX Board Pass No.
U1TRXSN Up1 TRX Slot No.
U1TRXSRN Up1 TRX Subrack No.
ucCSPrefCallReestPrio CS Preferred Call Reestablish Priority
ucCSPrefCSEmergCallPrio CS Preferred CS Emergency Call Priority
ucCSPrefCSOrgCallPrio CS Preferred CS MOC Priority
ucCSPrefCSTermCallPrio CS Preferred CS MTC Priority
ucCSPrefInBscHoPrio CS Preferred Into-BSC HO Priority
ucCSPrefIntraBscHoPrio CS Preferred Intra-BSC HO Priority
ucCSPrefOtherPrio CS Preferred Other Service Priority
ucCSPrefPSPrio CS Preferred PS Priority
ucCSPrefSupplePrio CS Preferred Supplement Priority
ucCSPrefVBSPrio CS Preferred VBS Priority
ucCSPrefVGCSPrio CS Preferred VGCS Priority
ucCtrlOfCicIE Controlling of CIC IE In BSS Map Messages
UCISRAIFAULT RAI Alarm Switch
ucPSPrefCallReestPrio PS Preferred Call Reestablish Service Priority
ucPSPrefCSEmergCallPrio PS Preferred CS Emergency Call Service Priority
ucPSPrefCSOrgCallPrio PS Preferred CS Original Call Service Priority
ucPSPrefCSTermCallPrio PS Preferred CS Terminated Call Service Priority
ucPSPrefInBscHoPrio PS Preferred In Handover Service Priority
ucPSPrefIntraBscHoPrio PS Preferred Intra Handover Service Priority
ucPSPrefOtherPrio PS Preferred Other Service Priority
ucPSPrefPSPrio PS Preferred PS Service Priority
ucPSPrefSupplePrio PS Preferred Supplement Service Priority
ucPSPrefVBSPrio PS Preferred VBS Service Priority
ucPSPrefVGCSPrio PS Preferred VGCS Service Priority
ucSpeechVerOptiInHo Speech Ver Change Optimize in Handover
UDPMUXMODRECV Receive UDP MUX Mode
UDPMUXMODSEND Sender UDP MUX Mode
UDPPN Local UDP Port No.
UDPPN Remote UDP Port No.
UG Operator Level
UHUMTHD Upper Humidity Threshold
UIC UIC
UINTTIME Unit time[ms]
UL Upper Limit
UL Upper Limit
ULADJPRD PwrCtrlULAdjPeriod
ULAFSREXQUALHIGHTHRED ULAFSRexQualHighThred
ULAFSREXQUALLOWTHRED ULAFSRexQualLowThred
ULAHSREXQUALHIGHTHRED ULAHSRexQualHighThred
ULAHSREXQUALLOWTHRED ULAHSRexQualLowThred
ULBQLASTTIME UL BQ HO Last Time
ULBQSTATTIME UL BQ HO Static Time
ULCOEFFICIENTTSRAPIDADJ Fast UL Priority Decision Threshold
ULDATAFWDTMR Timer for UL Data Forward
ulDlAckFreq RRBP Frequency for GPRS Downlink TBF
ULEDGETHRES Edge HO UL RX_LEV Threshold
ulEgprsDlAckFreq RRBP Frequency for EGPRS Downlink TBF
ulEgprsUlAckFreq ACK Frequency for EGPRS Uplink TBF
ULFILTADJFACTOR III UL Filter Adjust Factor
ULFSREXQUALHIGHTHRED ULFSRexQualHighThred
ULFSREXQUALLOWTHRED ULFSRexQualLowThred
ULHSREXQUALHIGHTHRED ULHSRexQualHighThred
ULHSREXQUALLOWTHRED ULHSRexQualLowThred
ULHYSTF1 AMR UL Coding Rate adj.hyst1[F]
ULHYSTF2 AMR UL Coding Rate adj.hyst2[F]
ULHYSTF3 AMR UL Coding Rate adj.hyst3[F]
ULHYSTH1 AMR UL Coding Rate adj.hyst1[H]
ULHYSTH2 AMR UL Coding Rate adj.hyst2[H]
ULHYSTH3 AMR UL Coding Rate adj.hyst3[H]
ULHYSTWB1 AMR UL Coding Rate adj.hyst1[WB]
ULHYSTWB2 AMR UL Coding Rate adj.hyst2[WB]
UlLdrThrd2GCell 2G Cell UL Basic Congest Thred
ULLEVFILTLEN Filter Length for UL RX_LEV
ULMAXDOWNSTEP ULMAXDownStep
ULMAXUPSTEP ULMAXUpStep
UlOlcThrd2GCell 2G Cell UL Overload Congest Thred
ULPREDLEND UL MR. Number Predicted
ULQHIGHTHRED UL Qual. Upper Threshold
ULQLOWTHRED UL Qual. Lower Threshold
ULQUAFILTLEN Filter Length for UL Qual.
ULQUALBADTRIG UL Qual. Bad Trig Threshold
ULQUALBADUPLEV UL Qual. Bad UpLEVDiff
ULQUALIMIT UL Qual. Threshold
ULQUALIMITAMRFR UL Qual. Limit for AMR FR
ULQUALIMITAMRHR UL Qual. Limit for AMR HR
ULREXLEVADJFCTR ULRexLevAdjustFactor
ULREXLEVEXPFLTLEN ULRexLevExponentFilterLen
ULREXLEVHIGHTHRED ULRexLevHighThred
ULREXLEVLOWTHRED ULRexLevLowThred
ULREXLEVSLDWINDOW ULRexLevSlideWindow
ULREXQUALADJFCTR ULRexQualAdjustFactor
ULREXQUALEXPFLTLEN ULRexQualExponentFilterLen
ULREXQUALSLDWINDOW ULRexQualSlideWindow
ULRXLEVPROTECTFACTOR III UL RexLev Protect Factor
ULRXQUALPROTECTFACTOR III UL RexQual Protect Factor
ULSSHIGHTHRED UL RX_LEV Upper Threshold
ULSSLOWTHRED UL RX_LEV Lower Threshold
ULTHF1 AMR UL Coding Rate adj.th1[F]
ULTHF2 AMR UL Coding Rate adj.th2[F]
ULTHF3 AMR UL Coding Rate adj.th3[F]
ULTHH1 AMR UL Coding Rate adj.th1[H]
ULTHH2 AMR UL Coding Rate adj.th2[H]
ULTHH3 AMR UL Coding Rate adj.th3[H]
ULTHWB1 AMR UL Coding Rate adj.th1[WB]
ULTHWB2 AMR UL Coding Rate adj.th2[WB]
ULTOOLHOALLOW UL to OL HO Allowed
ulUlAckFreq ACK Frequency for GPRS Uplink TBF
UMCROSSTALKOPTALLOWED Um Interface Crosstalk Optimization Allowed
UMPENALTYTIMER UmPenaltyTimer
UmVer Um Interface Tag
UNBA Support Balance
UNBLOCKRETRY Unblock Retry
UnderCurAlmThdA ANT_A ALD Under Current Occur Threshold
UnderCurAlmThdB ANT_B ALD Under Current Occur Threshold
UnderCurAlmThdRET RET ALD Under Current Occur Threshold
UnderCurClrThdA ANT_A ALD Under Current Clear Threshold
UnderCurClrThdB ANT_B ALD Under Current Clear Threshold
UnderCurClrThdRET RET ALD Under Current Clear Threshold
UPBTSID Up BTS Index
UPBTSID Dest Father BTS Index
UPBTSIDTYPE UPBTS Index type
UPBTSIDTYPE Dest Father Index Type
UPBTSNAME Up BTS Name
UPBTSNAME Dest Father BTS Name
UPDATE Update
UPDEFAULTCS Uplink Default CS Type
UPDEFAULTMCS Uplink Default MCS Type
Uplink Multiplex Threshold of Dynamic Channel
UPDYNCHNTRANLEV Conversion
UPE2ADEFAULTMCS Uplink EGPRS2-A Default MCS Type
UPE2AFIXMCS Uplink EGPRS2-A Fixed MCS Type
UPEXTTBFINACTDELAY Inactive Period of Extended Uplink TBF
UPFIXCS Uplink Fixed CS Type
UPFIXMCS Uplink Fixed MCS Type
UPINTERFQUALLIMIT Interf.of UL Qual. Threshold
UPINTERLEVLIMIT Interf.of UL Level Threshold
UPLNKMAXLENGTH Uplink Max Length
UPOMLWS OML/ESL/EML LAPD Uplink Window Size
UPPCEN UL PC Allowed
UPPERGRPID Upper Class Transport Resource Group No.
UPPERLP The Upper logic port number
UPRXLEVLASTTIME Duration of Uplink Received Level Differ
UPRXLEVSMOOTHPARA Smooth Factor of Uplink Received Level
UPRXLEVSTATICTIME Observe Time of UL RX Level Difference
UPSENDSMDIS Short Message Uplink Disabled
UPTBFRELDELAY Release Delay of Non-extended Uplink TBF
UPTHDCSDEGRADE1 Uplink TBF Threshold from CS2 to CS1
UPTHDCSDEGRADE2 Uplink TBF Threshold from CS3 to CS2
UPTHDCSDEGRADE3 Uplink TBF Threshold from CS4 to CS3
UPTHDCSUPGRADE1 Uplink TBF Threshold from CS1 to CS2
UPTHDCSUPGRADE2 Uplink TBF Threshold from CS2 to CS3
UPTHDCSUPGRADE3 Uplink TBF Threshold from CS3 to CS4
URGENTRESELALLOW Cell Urgent Reselection Allowed
USERIDTYPE User Query Type
USFGRAN4BLK Support USF Granularity 4 Switch
USR User Name of FTP Server
USR FTPServer User
USTBGNTIME Energy Saving Start Time[HH:MM]
USTENDTIME Energy Saving End Time[HH:MM]
UTEMTHD Upper Temperature Threshold
UTOOFAILMAXTIME MaxRetry Time after UtoO Fail
UTOOHOPENTIME Penalty Time of UtoO HO
UTOORECTH UtoO HO Received Level Threshold
UTOOTRAFHOALLOW UtoO Traffic HO Allowed
UTRAFHOPERIOD Underlay HO Step Period
UTRAFHOSTEP Underlay HO Step Level
UTRANCELLTYPE Utran Cell Type
VENDORCODE Vendor Code
VGCSMAXNUM Maximum Number of Channels for VGCS
VGCSPREEMPT Channel Allocation Strategy for VGCS
VGCSRSRVNUM Reserved Number of Channels for VGCS
VIPACCESSCPURATE VIP Access CPU Rate
VIPCELL VIP Cell
VIPPRIORITY VIP Priority
VIPSHAREINCPURATE VIP Share in CPU Rate
VLANFlAG VLANID Flag
VLANFLAG Vlan Flag
VLANFLAG1 VLANID Flag of First Local IP address
VLANFlAG2 VLANID Flag of Second Local IP address
VLANID VLAN ID.
VLANID VLAN ID
VLANID VLAN ID
VLANID VLAN ID
VLANID1 VLAN ID of First Local IP address
VLANID2 VLAN ID of Second Local IP address
VLANPRI VLAN Priority
VLANPRI VLAN Priority
VLANSWITCH VLAN Switch
VOICEVER Speech Version
VOL24_MASK Enable Alarm Reporting for 24V Power
VOL24_THD_HIGH Upper Limit of Alarm for 24V Power
VOL24_THD_LOW Lower Limit of Alarm for 24V Power
VOL48_MASK Enable Alarm Reporting for 48V Power
VOL48_THD_HIGH Upper Limit of Alarm for 48V Power
VOL48_THD_LOW Lower Limit of Alarm for 48V Power
VSWRENABLED Standing Wave Alarm CFG Enabled
VSWRERRTHRES VSWR TRX Unadjusted Threshold
VSWRFILETERCOUNTER Serious VSW Alarm Filter Times
VSWRTHRES1 Standing Wave Radio Alarm Threshold
VSWRTHRES2 Serious VSW Alarm Threshold
VSWRUNJUSTTHRES VSWR TRX Error Threshold
VVer V-Version No.
WAITFORRELIND T3109
WAITFORRELINDAMRFR Wait for REL Indication AMR FR
WAITFORRELINDAMRHR T3109 for AMR HR
WaitMSLocationResponse Timer of MS Location Response from MS
WAITRESVCHANREFRESHTIMER Timer of Reserved TCH for EMC
WAITSDCCHIDLETIMER IBCA Wait SDCCH Idle Timer
WaitSMLCLocationResponse Timer of MS Location Response from SMLC
WARMSET Heating Equipment
WATER_MASK Enable Water Alarm Reporting
WEEK Week Limit
WELONGI WE Longitude
WETSET Humidification Equipment
WHETHERAFFECTSWAP Whether affect the port swapping
WINADJSWITCH LAPD Window Adjust Switch
WK Week
WKMODE Work mode
WLAETIME End Time of WLA Detection
WLAFLAG Wireless Link Alarm Critical Permit
WLARP WLA Prompting Recover Period
WLASTIME Begin Time of WLA Detection
WLNKALMFLAG Wireless Link Alarm Flag
WORKAREA Work Area Flag
WORKINGSTANDARD Working Standard
WORKMODE Work Mode
WORKMODE Work Mode
WORKMODE Work Mode
WS Window Size
WTBS Wait Time before OML Switch
WTBS Ring I Wait Time Before Switch
WTRT WTR Time[Sec]
ZONET TimeZone
NE MML Command
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 ADD BTS(Optional)
BSC6900 SET GCELLCCCH(Optional)
BSC6900 SET BSCTMR(Optional)
BSC6900 SET BSCTMR(Optional)
BSC6900 SET BTSOTHPARA(Optional)
BSC6900 SET BTSOTHPARA(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BTSFLEXABISPARA(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET GCELLPRACH(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET GCELLCCBASIC(Mandatory)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 ADD BSCACCCTRLP(Mandatory)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 ADD BSCACCCTRLP(Optional)
BSC6900 ADD BSCACCCTRLP(Optional)
BSC6900 ADD BSCACCCTRLP(Optional)
ADD PPPLNK(Optional)
BSC6900 ADD MPGRP(Optional)
ADD BTSPPPLNK(Optional)
BSC6900 ADD BTSMPGRP(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLIDLEAD(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET GCELLSOFT(Optional)
SET BTSFMUABP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BTSRXUBP(Optional)
ADD EXTNCELL(Mandatory)
BSC6900 COL BSCSYNCINFO(Mandatory)
SET BTSEXCURSION(Mandatory)
BSC6900 SET BSCSYNCOFF(Mandatory)
BSC6900 SET GCELLEGPRSPARA(Optional)
BSC6900 SET BTSAUTODLDACTINFO(Optional)
BSC6900 SET BTSAUTODLDACTINFO(Optional)
BSC6900 SET GCELLADMSTAT(Mandatory)
BSC6900 SET GTRXADMSTAT(Mandatory)
BSC6900 SET GTRXCHANADMSTAT(Mandatory)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD AISSCFG(Mandatory)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD BTSALMMGMRULE(Mandatory)
BSC6900 SET BTSAUTODLDACTINFO(Optional)
BSC6900 SET BTSAUTODLDACTINFO(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 ADD GPS(Mandatory)
BSC6900 ADD GPS(Mandatory)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET ALMPORT(Mandatory)
BSC6900 SET ALMBLKPARA(Mandatory)
SET ALMLVL(Mandatory)
BSC6900 SET ALMSHLD(Mandatory)
BSC6900 ADD OBJALMSHLD(Optional)
BSC6900 SET ENVALMPARA(Mandatory)
BSC6900 SET BTSENVALMPORT(Optional)
BSC6900 ADD BTSOBJALMSHLD(Mandatory)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 ADD OBJALMSHLD(Optional)
BSC6900 ADD BTSOBJALMSHLD(Mandatory)
BSC6900 SET OTHSOFTPARA(Mandatory)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET BSCNSPARA(Optional)
BSC6900 SET BSCNSPARA(Optional)
BSC6900 ADD RSCGRP(Mandatory)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 ADD AE1T1(Mandatory)
BSC6900 ADD PBE1T1(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 ADD BTSALMMGMRULE(Mandatory)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSALMFLASHTHD(Mandatory)
BSC6900 ADD BTSALMMGMRULE(Mandatory)
BSC6900 SET BTSDGPSBP(Optional)
BSC6900 SET BTSDGPSBP(Optional)
BSC6900 SET BTSDGPSBP(Optional)
BSC6900 ADD BTSALMMGMRULE(Mandatory)
BSC6900 SET BTSALMFLASHTHD(Optional)
BSC6900 SET BTSALMFLASHTHD(Optional)
BSC6900 SET BTSALMFLASHTHD(Optional)
BSC6900 SET BTSALMFLASHTHD(Optional)
BSC6900 SET BTSDHEUBP(Optional)
EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 SET GCELLPSPWPARA(Optional)
BSC6900 SET GCELLLCS(Optional)
BSC6900 ADD GPS(Mandatory)
BSC6900 SET GCELLLCS(Optional)
BSC6900 ADD GPS(Mandatory)
BSC6900 EXP ALMLOG(Optional)
SET ALMLVL(Mandatory)
BSC6900 SET ALMSCRN(Mandatory)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET AITFOTHPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET BTSANTANGLE(Mandatory)
ADD ADJNODE(Mandatory)
BSC6900 ADD IPPATH(Mandatory)
ADD IPMUX(Mandatory)
BSC6900 ADD IPPATHBIND(Mandatory)
BSC6900 SET ENVALMPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET GCELLLCS(Optional)
SET BTSDGPSBP(Optional)
BSC6900 SET BTSUSCUBP(Optional)
SET BTSDGPSBP(Optional)
BSC6900 SET BTSUSCUBP(Optional)
BSC6900 ADD MPGRP(Optional)
BSC6900 SET BTSTHEFTALM(Optional)
LOD RETANTCFG(Mandatory)
BSC6900 SET BTSANTANGLE(Mandatory)
BSC6900 ADD TRXBIND2PHYBRD(Mandatory)
BSC6900 ADD BTSBINDLOCGRP(Optional)
ADD BTSANTFEEDERBRD(Mandatory)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 ADD MTP3LNK(Mandatory)
BSC6900 ADD SCTPLNK(Mandatory)
BSC6900 ADD SEMILINK(Mandatory)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCBASIC(Optional)
CMP BRDAREA(Optional)
BSC6900 LOD PATCH(Optional)
LOD BRD(Optional)
BSC6900 SYN BRDAREA(Optional)
BSC6900 SET GTRXRLALM(Optional)
BSC6900 SET GTRXRLALM(Optional)
BSC6900 SET GTRXRLALM(Optional)
BSC6900 STR IPCHK(Optional)
BSC6900 STR IPCHK(Optional)
BSC6900 ADD MTP3LNK(Mandatory)
ADD ATERSL(Optional)
BSC6900 ADD ATERCONSL(Optional)
BSC6900 ADD MTP3LNK(Mandatory)
EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 SET ENVALMPARA(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDEMUBP(Optional)
BSC6900 SET BTSRXUBP(Mandatory)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDEMUBP(Optional)
BSC6900 SET BTSRXUBP(Mandatory)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDEMUBP(Optional)
BSC6900 SET BTSRXUBP(Mandatory)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLTMR(Optional)
BSC6900 SET BSCTMR(Optional)
BSC6900 SET BSCAITFTMR(Optional)
BSC6900 SET BSCAITFTMR(Optional)
BSC6900 SET BSCAITFTMR(Optional)
BSC6900 SET BSCTMR(Optional)
BSC6900 SET BSCTMR(Optional)
BSC6900 SET BSCAITFTMR(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
ADD MTP3LNK(Mandatory)
BSC6900 ADD ATERE1T1(Mandatory)
BSC6900 SET BSSLS(Optional)
ADD MTP3LNK(Mandatory)
BSC6900 ADD ATERSL(Mandatory)
BSC6900 ADD SEMILINK(Mandatory)
BSC6900 ADD ATEROML(Mandatory)
BSC6900 ADD ATEROML(Mandatory)
ADD ATERSL(Optional)
BSC6900 ADD ATERCONSL(Optional)
BSC6900 SET BSCBASIC(Mandatory)
BSC6900 STR BTSVSWRTST(Optional)
BSC6900 ADD MTP3LNK(Mandatory)
BSC6900 SET GCELLIDLEBASIC(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET E1T1LOP(Optional)
BSC6900 STR E1T1TST(Optional)
BSC6900 SET SSLAUTHMODE(Mandatory)
BSC6900 ADD PPPLNK(Mandatory)
BSC6900 ADD MPGRP(Mandatory)
ADD BTSPPPLNK(Mandatory)
BSC6900 ADD BTSMPGRP(Mandatory)
BSC6900 ADD PPPLNK(Mandatory)
BSC6900 ADD MPGRP(Mandatory)
ADD BTSPPPLNK(Mandatory)
BSC6900 ADD BTSMPGRP(Mandatory)
BSC6900 ADD PPPLNK(Mandatory)
BSC6900 ADD MPGRP(Mandatory)
ADD BTSPPPLNK(Mandatory)
BSC6900 ADD BTSMPGRP(Mandatory)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPGRP(Optional)
ADD BTSPPPLNK(Optional)
BSC6900 ADD BTSMPGRP(Optional)
BSC6900 SET ETHPORT(Optional)
BSC6900 ADD BRD(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET BTSETHPORT(Optional)
BSC6900 SET BTSAUTODLDACTINFO(Optional)
BSC6900 LCK SCHTSK(Optional)
BSC6900 SET PWDPOLICY(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET ALMPORT(Optional)
BSC6900 SET BTSENVALMPORT(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET CLK(Optional)
BSC6900 SET CLK(Optional)
BSC6900 BKP LOGDB(Optional)
BSC6900 BKP DB(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 ADD BTSESN(Optional)
BSC6900 STR IPCHK(Optional)
BSC6900 STR IPCHK(Optional)
BSC6900 SET BTSBAKPWR(Mandatory)
BSC6900 SET BTSBAKPWR(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET BTSRACKBC(Mandatory)
BSC6900 ADD AISSCFG(Mandatory)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET SCTPSRVPORT(Optional)
BSC6900 SET GTRXRLALM(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 ADD GCELL(Optional)
BSC6900 ADD GEXT2GCELL(Mandatory)
BSC6900 ADD GCELLQUICKSETUP(Optional)
BSC6900 ADD GEXT2GCELL(Mandatory)
BSC6900 ADD GCELLQUICKSETUP(Mandatory)
BSC6900 SET GCELLHOPQUICKSETUP(Mandatory)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSTCDSCPMAP(Optional)
STR FRPORTLOOP(Mandatory)
BSC6900 BLK BC(Mandatory)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 ADD N7DPC(Mandatory)
BSC6900 SET GBSCREDGRP(Optional)
BSC6900 SET GCELLEGPRSPARA(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
SET GCELLHOUTRANFDD(Optional)
BSC6900 SET GCELLHOUTRANTDD(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 STR IPCHK(Optional)
ADD BTSBFD(Mandatory)
BSC6900 ADD BTSIPRTBIND(Mandatory)
BSC6900 SET GTRXRLALM(Optional)
BSC6900 SET GCELLCCACCESS(Optional)
SET BTSEXCURSION(Mandatory)
BSC6900 SET BSCSYNCOFF(Mandatory)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET ALMBLKSW(Optional)
BSC6900 SET ALMBLKPARA(Optional)
BSC6900 SET ALMBLKSW(Optional)
BSC6900 SET ALMBLKSW(Optional)
BSC6900 SET BSCNSPARA(Optional)
BSC6900 SET BSCNSPARA(Optional)
BSC6900 ADD ATERCONPATH(Mandatory)
BSC6900 ADD ATERCONPATH(Mandatory)
BSC6900 ADD ATERCONPATH(Mandatory)
BSC6900 SET BSCTMR(Optional)
ADD PPPLNK(Mandatory)
BSC6900 ADD MPGRP(Mandatory)
BSC6900 SET BOXRPT(Mandatory)
BSC6900 SET BTSBREAKPOINT(Optional)
BSC6900 SET BTSBREAKPOINT(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 STR BKP(Mandatory)
SET FCSW(Mandatory)
BSC6900 SET FCCPUTHD(Mandatory)
BSC6900 SET CPUTHD(Mandatory)
BSC6900 ADD BRD(Mandatory)
BSC6900 STR BTSLOG(Mandatory)
BSC6900 STR BTSVSWRTST(Optional)
ADD BTSBRDCAP(Mandatory)
BSC6900 ADD BTSRXUBRD(Optional)
BSC6900 LOD BTSSW(Mandatory)
ADD BTSBRDCAP(Mandatory)
BSC6900 ADD BTSRXUBRD(Optional)
BSC6900 SET DPUBRDTYPE(Mandatory)
BSC6900 ADD BRD(Optional)
BSC6900 SET ETHPORT(Mandatory)
BSC6900 ADD PPPLNK(Mandatory)
BSC6900 ADD MPGRP(Mandatory)
BSC6900 ADD MPLNK(Mandatory)
BSC6900 ADD BTSBRDCAP(Mandatory)
BSC6900 STR BTSLOG(Mandatory)
BSC6900 SET BTSRINGATTR(Optional)
BSC6900 SET GCELLSBC(Optional)
BSC6900 SET GCELLSBC(Optional)
BSC6900 BKP LOGDB(Optional)
BSC6900 SET GCELLIDLEBASIC(Optional)
BSC6900 ADD EXTBSC(Mandatory)
BSC6900 SET BSCDSTPA(Optional)
BLK ACIC(Mandatory)
BSC6900 ADD AE1T1(Mandatory)
BSC6900 ADD GCBSADDR(Mandatory)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD ADJNODE(Mandatory)
ADD GEXT2GCELL(Optional)
BSC6900 ADD EXTBSC(Mandatory)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD GCBSADDR(Mandatory)
ADD BTSAUTOPLAN(Mandatory)
BSC6900 SET BTSIP(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 ADD EXTBSC(Mandatory)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 ADD BTSMONITORTS(Mandatory)
BSC6900 ADD GCBSADDR(Mandatory)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 ADD BTSMONITORTS(Mandatory)
BSC6900 ADD BTSMONITORTS(Mandatory)
BSC6900 ADD BTSMONITORTS(Mandatory)
BSC6900 SET BSCAISS(Mandatory)
ADD ATERE1T1(Mandatory)
BSC6900 ADD ATERSL(Mandatory)
BSC6900 SET BSCBASIC(Mandatory)
BSC6900 ADD BTSMONITORTS(Mandatory)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET GCELLHOCTRL(Optional)
BSC6900 ADD GCELL(Optional)
BSC6900 SET GCELLIDLEBASIC(Optional)
BSC6900 ADD GCELL(Optional)
BSC6900 ADD GCELL(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 ADD GCNNODE(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET CLK(Mandatory)
BSC6900 CON PATCH(Mandatory)
LOD PATCH(Mandatory)
BSC6900 LOD BRD(Mandatory)
SET E1T1LOP(Mandatory)
BSC6900 SET E1T1(Mandatory)
BSC6900 LOP E1T1(Mandatory)
BSC6900 STR E1T1TST(Mandatory)
BSC6900 SET OPT(Mandatory)
BSC6900 SET COPTLNK(Mandatory)
BSC6900 ADD IPLOGICPORT(Mandatory)
BSC6900 CHK E1T1CRS(Mandatory)
BSC6900 ADD BTSRETANT(Mandatory)
BSC6900 ADD BTSANTFEEDERBRD(Mandatory)
BSC6900 ADD BTSBRD(Mandatory)
BSC6900 ADD BTSRXUBRD(Mandatory)
BSC6900 ADD BTSTRXBRD(Mandatory)
SET
BSC6900 BTSANTFEEDERCONNECT(Mandatory)
BSC6900 ADD ATERE1T1(Mandatory)
BSC6900 ADD ATERSL(Mandatory)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET BTSOMLDETECT(Mandatory)
BSC6900 SET BTSIP(Optional)
BSC6900 IMP BTSIPPARA(Mandatory)
BSC6900 ADD BTS(Optional)
BSC6900 SET BTSOTHPARA(Optional)
BSC6900 ADD ADJNODE(Mandatory)
SET BTSEXCURSION(Mandatory)
BSC6900 SET BSCSYNCOFF(Mandatory)
BSC6900 SET BSCABISPRIMAP(Mandatory)
BSC6900 ADD BTSABISHDLCPATH(Mandatory)
LOD BTSSW(Mandatory)
BSC6900 LOD BTSPATCH(Mandatory)
BSC6900 COL SYNCINFO(Mandatory)
BSC6900 SET BTSANTANGLE(Mandatory)
BSC6900 ADD BTSOP(Mandatory)
ADD BTSAUTOPLAN(Mandatory)
BSC6900 SET BTSIP(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 SET GCELLHOCTRL(Optional)
SET BTSEXCURSION(Mandatory)
BSC6900 SET BSCSYNCOFF(Mandatory)
BSC6900 ADD BTSABISHDLCPATH(Mandatory)
LOD BTSSW(Mandatory)
BSC6900 LOD BTSPATCH(Mandatory)
BSC6900 SET BTSPINGSW(Optional)
BSC6900 SET BTSLOCKBCCH(Mandatory)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 LOD BTSSW(Mandatory)
BSC6900 SET BTSTRCMPR(Mandatory)
ADD BTS(Mandatory)
BSC6900 SET BTSALM(Mandatory)
ADD BTSAUTOPLAN(Mandatory)
BSC6900 SET BTSAUTOPLANCFG(Mandatory)
LOD BTSPATCH(Mandatory)
BSC6900 CON BTSPATCH(Mandatory)
BSC6900 ADD BTSBFD(Optional)
BSC6900 STR BTSTST(Mandatory)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSRINGATTR(Optional)
BSC6900 ADD SCTPLNK(Optional)
ADD PTPBVC(Mandatory)
BSC6900 BLK PTPBVC(Mandatory)
BSC6900 ADD GCELLQUICKSETUP(Optional)
BSC6900 SET BSSGPPARA(Optional)
BSC6900 ADD IPLOGICPORT(Mandatory)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 ADD RSCGRP(Mandatory)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET GTRXRLALM(Optional)
ADD NCELL(Mandatory)
BSC6900 COL SYNCINFO(Mandatory)
BSC6900 SET GCELLRESELECTPARA(Optional)
BSC6900 SET GCELLRESELECTPARA(Optional)
BSC6900 ADD BTSCABINET(Optional)
BSC6900 SET BTSRACKBC(Mandatory)
BSC6900 ADD CAB(Mandatory)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET BTSCLKPARA(Mandatory)
BSC6900 SET GCELLCCCH(Optional)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 ADD BTSBRD(Optional)
BSC6900 ADD IPPATH(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 STR IPCHK(Optional)
BSC6900 SET GCELLIDLEBASIC(Optional)
BSC6900 ADD GCBSADDR(Mandatory)
BSC6900 ADD GCBSADDR(Mandatory)
BSC6900 ADD GCBSADDR(Optional)
BSC6900 ADD GCBSADDR(Mandatory)
BSC6900 SET BSCTMR(Optional)
BSC6900 SET GCELLIDLEBASIC(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET BSCTMR(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET CERTFILE(Optional)
BSC6900 SET GCELLCCCH(Optional)
BSC6900 SET GCELLCCCH(Optional)
BSC6900 SET BSCPSTCDSCPMAP(Optional)
BSC6900 ADD ETHMA(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELL2GBA1(Mandatory)
BSC6900 SET GCELL2GBA1(Mandatory)
BSC6900 SET GCELLHO2GBA2(Mandatory)
BSC6900 SET GCELLHO2GBA2(Mandatory)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLSERVPARA(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET BTSPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
ADD GCELLFREQ(Mandatory)
BSC6900 ADD GCELLMAGRP(Mandatory)
BSC6900 SET GMRSCOPE(Mandatory)
BSC6900 SET GCELLHOINTERRATLDB(Mandatory)
BSC6900 ADD BTSRETANT(Mandatory)
BSC6900 ADD BTSAUTOPLAN(Optional)
BSC6900 SAV GCELLTEMPLATE(Mandatory)
BSC6900 STR NCS(Mandatory)
BSC6900 SET FHO(Mandatory)
BSC6900 ADD BTSRETANT(Mandatory)
BSC6900 SET BTSANTANGLE(Mandatory)
BSC6900 ADD GCELL(Mandatory)
BSC6900 ADD GEXT3GCELL(Optional)
BSC6900 ADD GSMSCB(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
ADD GCELLFREQ(Mandatory)
BSC6900 ADD GCELLMAGRP(Mandatory)
BSC6900 SET GCELLHOINTERRATLDB(Mandatory)
ADD BTSAUTOPLAN(Mandatory)
BSC6900 SAV GCELLTEMPLATE(Mandatory)
BSC6900 ADD GSMSCB(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLCCAD(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GTRXFC(Optional)
BSC6900 SET CERTFILE(Mandatory)
SET BTSFMUABP(Mandatory)
BSC6900 SET BTSNFCBBP(Mandatory)
BSC6900 SET BTSIP(Optional)
BSC6900 SET BTSAUTOPLANCFG(Mandatory)
IMP BTSIPPARA(Mandatory)
BSC6900 IMP BTSVLAN(Mandatory)
BSC6900 SET BTSCABPARA(Mandatory)
BSC6900 SET BTSPOWERTYPE(Mandatory)
BSC6900 ADD OP(Mandatory)
ADD CCG(Mandatory)
BSC6900 SET CCGN(Mandatory)
BSC6900 ADD OP(Optional)
ADD ATERSL(Optional)
BSC6900 ADD ATERCONSL(Optional)
BSC6900 ADD PBSL(Optional)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 SET CCGN(Optional)
BSC6900 SET BTSIDLETS(Mandatory)
BSC6900 ADD ATERSL(Optional)
BSC6900 ADD ATERCONSL(Optional)
BSC6900 ADD PBSL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 CBN BTSRXUCHAIN(Mandatory)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
SET GCELLSBC(Optional)
BSC6900 ADD GSMSCB(Mandatory)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET AITFOTHPARA(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 ADD IPPATH(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 STR IPCHK(Optional)
BSC6900 ADD IPPATHBIND(Mandatory)
BSC6900 SET BTSAIRCON(Optional)
BSC6900 SET BTSAIRCON(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 STR IPCHK(Mandatory)
BSC6900 STR BTSTST(Mandatory)
BSC6900 SET BTSCHNFALLBACK(Mandatory)
BSC6900 SET TCPLYVOICE(Mandatory)
SET FHO(Mandatory)
BSC6900 SET GTRXCHANHOP(Mandatory)
BSC6900 STR BTSTST(Mandatory)
BSC6900 SET BTSCHNFALLBACK(Mandatory)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GPSCHRSCOPE(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET GTRXCHAN(Optional)
ADD GCELL(Mandatory)
BSC6900 ADD GEXT2GCELL(Mandatory)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 BLK ACIC(Mandatory)
BSC6900 BLK PBCIC(Mandatory)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 ADD DXXCONNECT(Mandatory)
BSC6900 ADD DXXCONNECT(Mandatory)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 ADD MPGRP(Optional)
BSC6900 SET BTSCLKPARA(Mandatory)
BSC6900 SET BTSIPCLKPARA(Optional)
BSC6900 SET CLKTYPE(Mandatory)
BSC6900 SET BTSCLK(Mandatory)
BSC6900 SET BTSTHEFTALM(Optional)
EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 SET BTSTHEFTALM(Optional)
BSC6900 EXP LOG(Optional)
BSC6900 ADD CCG(Mandatory)
BSC6900 ADD SUBCMD(Mandatory)
BSC6900 ADD CAB(Mandatory)
ADD TRXBIND2PHYBRD(Optional)
BSC6900 SWP BTSRING(Optional)
ADD BTSBFD(Optional)
BSC6900 ADD BTSIPRTBIND(Optional)
ADD BTSSFPMODE(Optional)
BSC6900 SET BTSFORBIDTS(Optional)
LOD RETANTCFG(Optional)
BSC6900 SET BTSANTANGLE(Optional)
BSC6900 OPR BTSBRDPWR(Mandatory)
BSC6900 SET GBSCREDGRP(Optional)
BSC6900 ADD GCNNODE(Mandatory)
ADD NSE(Mandatory)
BSC6900 ADD SGSNNODE(Mandatory)
ADD NRIMSCMAP(Mandatory)
BSC6900 SET MSGSOFTPARA(Mandatory)
BSC6900 CMP LICENSE(Optional)
BSC6900 SET GBSCREDGRP(Optional)
BSC6900 EXP ALMLOG(Optional)
BSC6900 SET BTSBAT(Mandatory)
BSC6900 SET BTSDPMUBP(Mandatory)
BSC6900 SET LOGLIMIT(Optional)
BSC6900 SET ALMBLKPARA(Optional)
BSC6900 SET ALMBLKPARA(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 ADD GSMSCB(Mandatory)
BSC6900 SET BTSOUTPUT(Optional)
BSC6900 COL SYNCINFO(Mandatory)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET PWDPOLICY(Optional)
BSC6900 SET BTSBWPARA(Optional)
BSC6900 ADD GEXT2GCELL(Optional)
BSC6900 ADD BTSABISHDLCPATH(Mandatory)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 ADD DXXCONNECT(Mandatory)
BSC6900 ADD SUBRACK(Optional)
BSC6900 SET CONNTYPE(Mandatory)
BSC6900 ADD GIURGCONN(Mandatory)
BSC6900 SET GCELLHOCTRL(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 PING IP(Optional)
PING MAC(Optional)
BSC6900 PING BTSCFM(Optional)
BSC6900 STR BTSTST(Mandatory)
BSC6900 SET GTRXDEV(Optional)
BSC6900 ADD GCBSADDR(Mandatory)
BSC6900 SET BTSCRC4(Mandatory)
BSC6900 SET GCELLIDLEBASIC(Optional)
BSC6900 SET CERTFILE(Mandatory)
BSC6900 SET CERTFILE(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLIDLEBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 SET GCSCHRCTRL(Optional)
BSC6900 SET GCSCHRCTRL(Optional)
BSC6900 SET GCSCHRCTRL(Optional)
BSC6900 SET GCSCHRCTRL(Optional)
BSC6900 ADD TRMFACTOR(Optional)
BSC6900 ADD TRMMAP(Optional)
BSC6900 ADD TRMMAP(Optional)
BSC6900 ADD TRMFACTOR(Optional)
BSC6900 ADD GCELL(Optional)
BSC6900 SET GCSCHRCTRL(Optional)
BSC6900 SET GCSCHRCTRL(Optional)
BSC6900 SET GCSCHRCTRL(Optional)
BSC6900 SET GCSCHRCTRL(Optional)
BSC6900 SET GCSCHRCTRL(Optional)
BSC6900 SET GCSCHRCTRL(Mandatory)
BSC6900 SET GCSCHRCTRL(Optional)
BSC6900 SET GTRXFC(Optional)
BSC6900 SET GCSCHRCTRL(Optional)
BSC6900 ADD TRMFACTOR(Optional)
BSC6900 SET GCSCHRCTRL(Optional)
BSC6900 ADD TRMMAP(Optional)
BSC6900 ADD TRMMAP(Optional)
BSC6900 ADD TRMFACTOR(Optional)
BSC6900 ADD GCELL(Optional)
BSC6900 SET SLFSLVSW(Optional)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 SET FCCPUTHD(Optional)
BSC6900 SET FCMSGQTHD(Optional)
BSC6900 ADD AISSCFG(Mandatory)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET BTSLOADCTRL(Mandatory)
BSC6900 ADD BTSRETANT(Mandatory)
BSC6900 ADD BTSRETANT(Mandatory)
BSC6900 ADD BTSRETANT(Mandatory)
BSC6900 ADD BTSRETANT(Mandatory)
BSC6900 ADD RSCGRP(Mandatory)
BSC6900 SET BTSCTRL(Mandatory)
BSC6900 SET BTSCTRL(Mandatory)
BSC6900 SET CMCTRLSW(Mandatory)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET BTSAUTODLDACTINFO(Mandatory)
BSC6900 SET GCSFILE(Optional)
BSC6900 UPD JTGCPLD(Mandatory)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 ADD OP(Optional)
BSC6900 SET TIME(Optional)
BSC6900 ADD BSCDSTPADATE(Mandatory)
BSC6900 SET BTSAUTODLDACTINFO(Mandatory)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 ADD GCELL(Mandatory)
BSC6900 ADD GCELL(Mandatory)
BSC6900 ADD GCELL(Mandatory)
BSC6900 ADD GCELL(Mandatory)
BSC6900 SET BTSALMPORT(Mandatory)
BSC6900 SET BTSALMPORT(Mandatory)
BSC6900 SET BTSALMPORT(Mandatory)
BSC6900 SET BTSALMPORT(Mandatory)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLTMR(Optional)
ADD M3DE(Mandatory)
BSC6900 ADD M3RT(Mandatory)
BSC6900 ADD OP(Optional)
BSC6900 SET BTSOUTPUT(Optional)
BSC6900 PING IP(Mandatory)
BSC6900 TRC IPADDR(Mandatory)
BSC6900 ADD IPRTBIND(Mandatory)
PING MAC(Mandatory)
BSC6900 TRC MAC(Mandatory)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 ADD BTSCONNECT(Mandatory)
BSC6900 ADD GIURGCONN(Mandatory)
BSC6900 ADD GIURGCONN(Mandatory)
BSC6900 ADD GIURGCONN(Mandatory)
BSC6900 MOV BCCH(Mandatory)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 ADD BTSBFD(Optional)
BSC6900 SET BTSABISTROP(Mandatory)
BSC6900 ADD BTSRETANT(Mandatory)
BSC6900 ADD BTSRETANT(Mandatory)
ADD PPPLNK(Mandatory)
BSC6900 ADD MPGRP(Mandatory)
BSC6900 ADD DEVIP(Mandatory)
ADD GEXT3GCELL(Mandatory)
BSC6900 SET GCELLHOFDDBA2(Mandatory)
BSC6900 SET BTSDFCUBP(Optional)
BSC6900 SET BTSDFCUBP(Optional)
BSC6900 ADD GCNNODE(Optional)
BSC6900 SET FTPSSRV(Mandatory)
BSC6900 ADD GPS(Optional)
BSC6900 ADD DHCPRLY(Mandatory)
BSC6900 ADD DHCPRLY(Mandatory)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 ADD SUBTSK(Mandatory)
BSC6900 ADD SUBTSK(Mandatory)
DLD LICENSE(Mandatory)
BSC6900 ULD LICENSE(Mandatory)
DLD RETANTCFG(Optional)
BSC6900 DLD BTSPATCH(Optional)
BSC6900 SET AITFOTHPARA(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
ADD GEXT3GCELL(Mandatory)
BSC6900 SET GCELLHOFDDBA2(Mandatory)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 ADD NSVC(Mandatory)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLPRIVATEOPTPARA(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
ADD BTSANTFEEDERBRD(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
ADD BTSANTFEEDERBRD(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET BTSIPCLKPARA(Mandatory)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLEGPRSPARA(Optional)
BSC6900 SET GCELLEGPRSPARA(Optional)
BSC6900 SET GCELLEGPRSPARA(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLEGPRSPARA(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLCCAD(Optional)
BSC6900 SET GCELLPRIVATEOPTPARA(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 ADD N7DPC(Mandatory)
BSC6900 ADD N7DPC(Mandatory)
BSC6900 BLK ACIC(Mandatory)
BSC6900 ADD AE1T1(Optional)
BSC6900 ADD GCNNODE(Mandatory)
BSC6900 ADD N7DPC(Mandatory)
ADD N7DPC(Mandatory)
BSC6900 ADD MTP3RT(Mandatory)
BSC6900 ADD GNRNC(Mandatory)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 SET BTSBAKPWR(Optional)
BSC6900 SET BTSBAKPWR(Optional)
BSC6900 SET BTSBAKPWR(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET BTSOUTPUT(Optional)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPLNK(Optional)
ADD SCTPLNK(Optional)
BSC6900 SET PHBMAP(Mandatory)
BSC6900 PING IP(Optional)
BSC6900 SET DSCPMAP(Mandatory)
SET BTSVLAN(Optional)
BSC6900 IMP BTSVLAN(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 DLD TCFILE(Mandatory)
BSC6900 SET TCTYPE(Optional)
BSC6900 ADD OBJALMSHLD(Mandatory)
SET TCPLYVOICE(Mandatory)
BSC6900 SET TCPARA(Optional)
BSC6900 SET PSCELLTODSP(Mandatory)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET TZ(Optional)
BSC6900 ULD BTSDEVFILE(Mandatory)
BSC6900 ADD IPRT(Mandatory)
BSC6900 ADD BTSBFD(Mandatory)
ADD BTSIPRT(Mandatory)
BSC6900 ADD BTSIPRTBIND(Mandatory)
BSC6900 ADD IPRT(Mandatory)
ADD BTSIPRT(Mandatory)
BSC6900 ADD BTSIPRTBIND(Mandatory)
BSC6900 ADD TSCROSS(Mandatory)
BSC6900 ADD TSCROSS(Mandatory)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 ADD BTSANTFEEDERBRD(Mandatory)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 ADD BTSANTFEEDERBRD(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 ADD BTSANTFEEDERBRD(Mandatory)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 ADD BTSANTFEEDERBRD(Mandatory)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET BTSETHPORT(Optional)
BSC6900 STR BTSTST(Mandatory)
BSC6900 STR TRXBURSTTST(Mandatory)
BSC6900 STR BTSTST(Mandatory)
BSC6900 STR BTSTST(Mandatory)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD BTSCONNECT(Mandatory)
ADD DXX(Mandatory)
BSC6900 ADD DXXCONNECT(Mandatory)
BSC6900 ADD BTSCONNECT(Mandatory)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 STR TRANSPERFTST(Mandatory)
BSC6900 STR TRANSPERFTST(Mandatory)
BSC6900 ADD BTSABISHDLCPATH(Mandatory)
BSC6900 STR TRANSPERFTST(Mandatory)
BSC6900 SET COPTLNK(Optional)
BSC6900 SET BTSCLK(Mandatory)
BSC6900 ADD BTSTOPCONFIG(Mandatory)
BSC6900 SET BTSCLK(Mandatory)
BSC6900 ADD IPPATH(Mandatory)
BSC6900 ADD G3GNCELL(Optional)
BSC6900 ADD GEXT3GCELL(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 ADD SUBTSK(Optional)
BSC6900 EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 STR BTSLOG(Optional)
BSC6900 SET TZ(Mandatory)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET BTSLOADCTRL(Mandatory)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET TZ(Mandatory)
BSC6900 SET GCELLCCAD(Optional)
BSC6900 ADD MTP3LKS(Optional)
BSC6900 ADD MPGRP(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET BSCSRVPRI(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET TZ(Mandatory)
BSC6900 ADD EMSIP(Mandatory)
BSC6900 SET BTSFALLBACK(Optional)
BSC6900 SET BTSTMA(Mandatory)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET FTPSSRV(Optional)
BSC6900 SET FTPSCLT(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 BLK ACIC(Mandatory)
BSC6900 BLK PBCIC(Mandatory)
BSC6900 ADD BSCDSTPADATE(Mandatory)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 ADD BSCDSTPADATE(Mandatory)
BSC6900 SET BTSFORBIDTS(Optional)
BSC6900 SET BSCDSTPA(Optional)
BSC6900 BLK ATERE1T1(Mandatory)
BSC6900 BLK AE1T1(Mandatory)
BSC6900 SET BTSFORBIDTS(Mandatory)
BSC6900 SET SCHTSKSW(Mandatory)
BSC6900 ADD SUBTSK(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 ADD GCELL(Mandatory)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 ADD M3LE(Mandatory)
BSC6900 ADD M3DE(Mandatory)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 EXP LOG(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
SET ETHPORT(Optional)
BSC6900 ADD PPPLNK(Optional)
SET ETHPORT(Optional)
BSC6900 ADD PPPLNK(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET BSCSRVPRI(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 EXP ALMLOG(Optional)
BSC6900 SET GCELLTMR(Optional)
BSC6900 SET AITFOTHPARA(Optional)
BSC6900 SET BTSRINGATTR(Optional)
BSC6900 SET TZ(Mandatory)
BSC6900 EXP LOG(Optional)
BSC6900 ADD SUBTSK(Mandatory)
BSC6900 RUN BATCHFILE(Optional)
BSC6900 COL LOG(Optional)
BSC6900 EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 ADD GSMSCB(Mandatory)
BSC6900 ADD OP(Mandatory)
BSC6900 STR BTSLOG(Optional)
BSC6900 EXP LOG(Optional)
BSC6900 ADD OP(Mandatory)
BSC6900 SET TZ(Mandatory)
BSC6900 SET TZ(Mandatory)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 SET GCELLSERVPARA(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 ADD GEXT2GCELL(Mandatory)
BSC6900 ADD GEXT2GCELL(Mandatory)
BSC6900 ADD GEXT3GCELL(Mandatory)
BSC6900 ADD GEXT3GCELL(Mandatory)
BSC6900 ADD EXTNCELL(Mandatory)
BSC6900 ADD EXTNCELL(Mandatory)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 SET BTSALM(Optional)
BSC6900 SET GCELLEXTMSRPARA(Optional)
BSC6900 SET GCELLEXTMSRPARA(Optional)
BSC6900 SET GCELLEXTMSRPARA(Optional)
BSC6900 ADD GCELL(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET FANSPEED(Optional)
BSC6900 SET FANSPEED(Optional)
BSC6900 SET FANSPEED(Optional)
BSC6900 SET FANSPEED(Optional)
BSC6900 SET FANSPEED(Mandatory)
BSC6900 SET FANSPEED(Mandatory)
BSC6900 LOD FAN(Mandatory)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET BTSRINGATTR(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET ETHPORT(Optional)
BSC6900 SET BTSETHPORT(Optional)
BSC6900 SET GTRXFC(Optional)
BSC6900 SET ETHPORT(Mandatory)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPGRP(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Mandatory)
BSC6900 ADD ETHTRK(Optional)
BSC6900 SET BSCABISPRIMAP(Mandatory)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 ADD BTSCONNECT(Optional)
BSC6900 SET GTRXFC(Optional)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPLNK(Optional)
BSC6900 SET FCSW(Mandatory)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET GCELLIDLEFDDBA1(Mandatory)
BSC6900 SET GCELLHOFDDBA2(Mandatory)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLIDLEFDDBA1(Mandatory)
BSC6900 SET GCELLIDLEFDDBA1(Mandatory)
BSC6900 ADD GEXT3GCELL(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 ADD GEXT3GCELL(Optional)
BSC6900 SET GCELLIDLEFDDBA1(Mandatory)
BSC6900 SET FCCPUTHD(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
SET GCELLHOPTP(Optional)
BSC6900 SET GCELLHOPQUICKSETUP(Mandatory)
BSC6900 EXP LOG(Optional)
BSC6900 ZIP FILE(Mandatory)
BSC6900 BKP LOGDB(Optional)
EXP CFGMML(Optional)
BSC6900 EXP GCELLTEMPLATE(Optional)
BSC6900 EXP ALMLOG(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 EXP LOG(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET BTSOUTPUT(Optional)
BSC6900 SET BTSFLEXABISPARA(Optional)
BSC6900 SET BTSALMFLASHTHD(Optional)
BSC6900 SET BTSALMFLASHTHD(Optional)
BSC6900 SET BTSALMFLASHTW(Optional)
BSC6900 SET BTSALMFLASHTW(Optional)
BSC6900 SET BTSALMFLASHTW(Optional)
BSC6900 ADD BTS(Optional)
BSC6900 ADD GCELL(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET ETHPORT(Optional)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPGRP(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 ADD ETHTRK(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLCCCH(Optional)
BSC6900 SET BTSFMUABP(Optional)
BSC6900 EXP ELABEL(Optional)
DLD LICENSE(Mandatory)
BSC6900 ULD LICENSE(Mandatory)
BSC6900 EXP DEVFILE(Optional)
EXP CFGMML(Optional)
BSC6900 BKP DB(Optional)
CHK DATA2LIC(Optional)
BSC6900 RVK LICENSE(Optional)
DLD RETANTCFG(Mandatory)
BSC6900 EXP BTSDEVFILE(Optional)
BSC6900 DLD BTSPATCH(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 ADD GCNNODE(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 ADD BTSCONNECT(Mandatory)
BSC6900 ADD IPMUX(Optional)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 ADD MPGRP(Optional)
SET BTSEXCURSION(Mandatory)
BSC6900 SET BSCSYNCOFF(Mandatory)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 EXP LOG(Mandatory)
BSC6900 ADD SUBTSK(Mandatory)
BSC6900 ADD GTRX(Mandatory)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
ADD GCELLFREQ(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 ADD BTSANTFEEDERBRD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLFREQSCAN(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 STR NCS(Mandatory)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 ADD BTSCONNECT(Optional)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 ADD BTSCONNECT(Optional)
BSC6900 EXP LOG(Optional)
BSC6900 ADD ADJMAP(Mandatory)
BSC6900 ADD TRMFACTOR(Mandatory)
BSC6900 SET BSCABISPRIMAP(Mandatory)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET TCPARA(Optional)
BSC6900 SET GCELLPSPWPARA(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD AISSCFG(Mandatory)
BSC6900 ADD AISSCFG(Optional)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 ADD GPS(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GLOBALROUTESW(Mandatory)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLGPRS(Mandatory)
BSC6900 ADD GCELLQUICKSETUP(Optional)
BSC6900 SET GCELLRESELECTPARA(Optional)
BSC6900 SET GTRXCHAN(Optional)
BSC6900 SET GCELLSERVPARA(Optional)
BSC6900 SET GCELLNCRESELECTPARA(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLNCRESELECTPARA(Optional)
SET BTSDGPSBP(Optional)
BSC6900 SET BTSUSCUBP(Optional)
BSC6900 ADD GPS(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 SET BTSCHNFALLBACK(Mandatory)
BSC6900 SET BTSCHNFALLBACK(Mandatory)
BSC6900 SET GBSCREDGRP(Mandatory)
BSC6900 SET GBSCREDGRP(Optional)
BSC6900 SET BTSFLEXABISPARA(Optional)
ADD RSCGRP(Mandatory)
BSC6900 SET BTSIP(Mandatory)
BSC6900 ADD RSCGRP(Mandatory)
SET GCELLSBC(Optional)
BSC6900 ADD GSMSCB(Mandatory)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 ADD ICMPGUARD(Mandatory)
BSC6900 ADD BTSAUTOPLAN(Optional)
BSC6900 SET BTSIP(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 ADD BTSRXUCHAIN(Mandatory)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET BTSBAT(Optional)
BSC6900 SET BTSBAT(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET PWDPOLICY(Optional)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 ADD GCNOPERATOR(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET FHO(Mandatory)
BSC6900 SET FHO(Mandatory)
SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLHOFAST(Optional)
BSC6900 SET GCELLHOFAST(Optional)
BSC6900 SET GCELLHOFAST(Optional)
BSC6900 SET GCELLHOFAST(Optional)
BSC6900 ADD G3GNCELL(Optional)
BSC6900 ADD G3GNCELL(Optional)
BSC6900 SET GCELLHOUTRANFDD(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET FHO(Mandatory)
ADD GEXT2GCELL(Optional)
BSC6900 SET GCELLHOFAST(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
SET GCELLHOUTRANFDD(Optional)
BSC6900 SET GCELLHOUTRANTDD(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 ADD GCELLMAGRP(Mandatory)
BSC6900 SET GCELLMAIOPLAN(Mandatory)
BSC6900 ADD GCELLMAGRP(Mandatory)
BSC6900 SET GCELLOTHBASIC(Optional)
SET GCELLHOUTRANFDD(Optional)
BSC6900 SET GCELLHOUTRANTDD(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Mandatory)
BSC6900 SET GTRXHOP(Optional)
ADD GEXT2GCELL(Optional)
BSC6900 SET GCELLHOFAST(Optional)
BSC6900 ADD AISSCFG(Optional)
SET GCELLHOUTRANFDD(Optional)
BSC6900 SET GCELLHOUTRANTDD(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 ADD G3GNCELL(Optional)
BSC6900 ADD G3GNCELL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 ADD OPC(Optional)
BSC6900 SET BTSIP(Optional)
ADD GEXT2GCELL(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOFAST(Optional)
BSC6900 SET GCELLHOPANT(Optional)
SET
BSC6900 GCELLHOPANTQUICKSETUP(Mandatory)
BSC6900 ADD BTSRXUCHAIN(Mandatory)
BSC6900 SET GCELLCHMGBASIC(Optional)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET GCELLCCCH(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 ADD GCELLMAGRP(Optional)
BSC6900 ADD BTSRXUCHAIN(Mandatory)
BSC6900 ADD GCELL(Optional)
BSC6900 ADD BTSRXUCHAIN(Mandatory)
BSC6900 ADD BTSBFD(Mandatory)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSAIRCON(Optional)
BSC6900 SET SCCPTMR(Optional)
BSC6900 STR TRANSPERFTST(Mandatory)
BSC6900 STR TRANSPERFTST(Mandatory)
BSC6900 STR TRANSPERFTST(Mandatory)
BSC6900 SET SCCPTMR(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 ADD IPPATH(Optional)
BSC6900 SET BSCPSTCDSCPMAP(Optional)
BSC6900 SET BSCPSTCDSCPMAP(Optional)
BSC6900 SET BSCPSTCDSCPMAP(Optional)
ADD SCHTSK(Mandatory)
BSC6900 SET SCHTSKSW(Optional)
BSC6900 STR SCHTSK(Optional)
BSC6900 ADD BTSBRDCAP(Mandatory)
BSC6900 SET TCPARA(Optional)
BSC6900 SET E1T1LOP(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
SET BTSEXCURSION(Mandatory)
BSC6900 ADD EXTNCELL(Mandatory)
ADD BTSESN(Mandatory)
BSC6900 SET BSCABISPRIMAP(Mandatory)
ADD GCELLFREQ(Mandatory)
BSC6900 ADD GCELLMAGRP(Mandatory)
BSC6900 ADD G2GNCELL(Mandatory)
BSC6900 SET GCELLHOINTERRATLDB(Mandatory)
ADD PTPBVC(Mandatory)
BSC6900 SET GCELLEGPRSPARA(Mandatory)
SET BTSFMUABP(Mandatory)
BSC6900 SET BTSNFCBBP(Mandatory)
SET BTSSHARING(Mandatory)
BSC6900 ADD BTSSFPMODE(Mandatory)
BSC6900 ADD SEMILINK(Mandatory)
SET MSTOCELL(Mandatory)
BSC6900 TST SNDRSI(Mandatory)
BSC6900 SET PSCELLTODSP(Mandatory)
BSC6900 ADD GCBSADDR(Optional)
ADD BTSIPRT(Mandatory)
BSC6900 IMP BTSIPRT(Mandatory)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
STR BTSLOG(Optional)
BSC6900 ULD BTSLOG(Optional)
BSC6900 SET GCELLHOFAST(Optional)
CHK INNSPCH(Mandatory)
BSC6900 STR CALLRESLOP(Mandatory)
BSC6900 SET GCELLTMR(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 SET GCELLTMR(Optional)
CHK INNSPCH(Mandatory)
BSC6900 STR CALLRESLOP(Mandatory)
SET MSTOCELL(Mandatory)
BSC6900 TST SNDRSI(Mandatory)
BSC6900 SET GCELLTMR(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 SET GCELLLCS(Optional)
BSC6900 ADD BTSCONNECT(Optional)
BSC6900 SET BTSDOMUBP(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 ADD GNRNC(Mandatory)
BSC6900 ADD EMU(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 ADD SEMILINK(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 ADD EXTNCELL(Mandatory)
BSC6900 ADD EXTNCELL(Mandatory)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 ADD SEMILINK(Mandatory)
BSC6900 ADD BTSCONNECT(Mandatory)
BSC6900 ADD DXXTSEXGRELATION(Mandatory)
BSC6900 SET GCELLLCS(Optional)
BSC6900 SET GCELLHOCTRL(Optional)
BSC6900 ADD SEMILINK(Mandatory)
BSC6900 ADD BTSCONNECT(Optional)
BSC6900 ADD SEMILINK(Mandatory)
BSC6900 ADD BTSCONNECT(Optional)
BSC6900 ADD GSMSCB(Mandatory)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 EXP LOG(Optional)
BSC6900 STR ETHOAMLOOPTST(Optional)
BSC6900 SET GCELLEXTMSRPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLTMR(Optional)
BSC6900 SET GCELLTMR(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLTMR(Optional)
BSC6900 ADD GNRNC(Mandatory)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 ADD SEMILINK(Mandatory)
BSC6900 ADD DXXTSEXGRELATION(Mandatory)
BSC6900 ADD SUBTSK(Optional)
BSC6900 SET ASWPARA(Mandatory)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 ADD XPUVLAN(Mandatory)
EXP LOG(Optional)
BSC6900 ADD SNTPSRVINFO(Mandatory)
BSC6900 ADD NSVLLOCAL(Mandatory)
BSC6900 ADD NSVLREMOTE(Mandatory)
SET BTSETHPORT(Optional)
BSC6900 IMP BTSDEVIP(Optional)
DLD RETANTCFG(Mandatory)
BSC6900 ULD BTSDEVFILE(Mandatory)
BSC6900 ADD IPPATH(Mandatory)
BSC6900 ADD DEVIP(Mandatory)
BSC6900 ADD ETHIP(Mandatory)
BSC6900 ADD ICMPGUARD(Mandatory)
BSC6900 ADD VLANID(Mandatory)
BSC6900 ADD ETHTRKIP(Mandatory)
BSC6900 ADD SGSNROUTEINFO(Mandatory)
BSC6900 ADD SGSN(Mandatory)
BSC6900 SET BTSIPCLKPARA(Mandatory)
BSC6900 ADD SGSN(Optional)
BSC6900 SET BTSIPCLKPARA(Mandatory)
BSC6900 ADD SGSN(Optional)
BSC6900 ADD SGSN(Optional)
SET BTSETHPORT(Optional)
BSC6900 ADD BTSPPPLNK(Optional)
SET BTSETHPORT(Optional)
BSC6900 ADD BTSPPPLNK(Optional)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPGRP(Optional)
BSC6900 ADD ETHIP(Mandatory)
BSC6900 ADD ETHTRKIP(Mandatory)
BSC6900 ADD IPMUX(Optional)
BSC6900 ADD BTS(Optional)
ADD BTSAUTOPLAN(Optional)
BSC6900 IMP BTSIPPARA(Mandatory)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 ADD AISSCFG(Mandatory)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET BTSIPCLKPARA(Mandatory)
BSC6900 SET BTSIPCLKPARA(Mandatory)
BSC6900 ADD BTS(Optional)
BSC6900 ADD BTSRXUBRD(Optional)
BSC6900 ADD GEXT2GCELL(Optional)
BSC6900 ADD RSCGRP(Mandatory)
BSC6900 ADD GEXT2GCELL(Optional)
BSC6900 ADD GTRX(Optional)
BSC6900 SET BSCBASIC(Mandatory)
BSC6900 ADD BTSLOCGRP(Mandatory)
BSC6900 ADD GEXT2GCELL(Optional)
BSC6900 ADD NSE(Optional)
BSC6900 ADD IPMUX(Mandatory)
BSC6900 ADD AISSCFG(Mandatory)
BSC6900 SET BTSENVALM(Mandatory)
BSC6900 SET BTSOTHPARA(Optional)
BSC6900 SET BTSLSW(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 ADD BRD(Mandatory)
BSC6900 ADD SUBRACK(Optional)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 SET BTSPSUFP(Optional)
SET GCELLIDLEFDDBA1(Mandatory)
BSC6900 SET GCELLIDLETDDBA1(Mandatory)
BSC6900 SET GCELLREV(Mandatory)
SET GCELLIDLEFDDBA1(Mandatory)
BSC6900 SET GCELLIDLETDDBA1(Mandatory)
BSC6900 SET GCELLREV(Mandatory)
ADD IPPATH(Mandatory)
BSC6900 ADD ADJMAP(Mandatory)
ADD BTSIPRT(Mandatory)
BSC6900 IMP BTSIPRT(Mandatory)
BSC6900 SET GTRXIUO(Mandatory)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 ADD GCELL(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET OPT(Mandatory)
BSC6900 SET OPT(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET OPT(Mandatory)
BSC6900 SET OPT(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET COPTLNK(Optional)
BSC6900 SET COPTLNK(Optional)
BSC6900 SET COPTLNK(Optional)
BSC6900 SET COPTLNK(Optional)
BSC6900 SET COPTLNK(Optional)
SET OPT(Optional)
BSC6900 SET COPTLNK(Optional)
BSC6900 SET BTSJBF(Mandatory)
BSC6900 SET BTSOTHPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET MSP(Optional)
BSC6900 SET GCELLHOAD(Optional)
ADD PPPLNK(Optional)
BSC6900 ADD MPLNK(Optional)
ADD GCELL(Mandatory)
BSC6900 ADD GEXT2GCELL(Mandatory)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 ADD ETHTRK(Mandatory)
BSC6900 SET GCELLLCS(Mandatory)
BSC6900 SET GCELLLCS(Mandatory)
BSC6900 SET GCELLLCS(Mandatory)
BSC6900 SET GCELLLCS(Mandatory)
BSC6900 SET GCELLLCS(Mandatory)
BSC6900 SET GCELLLCS(Mandatory)
BSC6900 ADD GPS(Mandatory)
BSC6900 ADD GPS(Mandatory)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 ADD GEXT2GCELL(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 ADD GEXTSMLC(Optional)
BSC6900 ADD GEXTSMLC(Optional)
BSC6900 SET LDR(Optional)
BSC6900 SET LDR(Optional)
BSC6900 SET LDR(Optional)
ADD M3LE(Mandatory)
BSC6900 ADD M3DE(Mandatory)
BSC6900 EXP LOG(Optional)
BSC6900 COL LOG(Optional)
BSC6900 SET ALMML(Mandatory)
BSC6900 ADD ETHMD(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 ADD BRD(Optional)
CON PATCH(Optional)
BSC6900 LOD PATCH(Optional)
ADD PPPLNK(Mandatory)
BSC6900 ADD MPGRP(Mandatory)
BSC6900 ADD BRD(Optional)
BSC6900 ADD PBSL(Optional)
BSC6900 SET BTSEXD(Optional)
BSC6900 SET LICALMTHD(Mandatory)
BSC6900 SET LICALMTHD(Mandatory)
BSC6900 LOP LAPDLNK(Mandatory)
BSC6900 EXP GCELLTEMPLATE(Optional)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 SET ALMPORT(Optional)
BSC6900 SET BTSENVALMPORT(Optional)
BSC6900 SET E1T1LOP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET OPT(Optional)
BSC6900 ADD SEMILINK(Optional)
BSC6900 ADD M3LNK(Optional)
BSC6900 ADD MTP3LKS(Optional)
BSC6900 ADD M3LKS(Optional)
ADD GEXT2GCELL(Optional)
BSC6900 ADD GEXT3GCELL(Optional)
BSC6900 ADD GCNOPERATOR(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BTSPMUBP(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 ADD GEXT2GCELL(Optional)
BSC6900 ADD GEXT3GCELL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET GBSCREDGRP(Mandatory)
BSC6900 ADD PPPLNK(Mandatory)
BSC6900 ADD MPGRP(Mandatory)
ADD BTSPPPLNK(Mandatory)
BSC6900 IMP BTSPPPLNK(Mandatory)
ADD BTSMPGRP(Mandatory)
BSC6900 IMP BTSMPGRP(Mandatory)
BSC6900 ADD NSVLLOCAL(Mandatory)
BSC6900 ADD SGSNROUTEINFO(Mandatory)
ADD BTSLOCGRP(Mandatory)
BSC6900 ADD BTSRXU2LOCGRP(Mandatory)
BSC6900 ADD BTSOBJALMSHLD(Mandatory)
EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 ADD SCTPLNK(Mandatory)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 SET OPLOCK(Mandatory)
BSC6900 ADD SCTPLNK(Mandatory)
BSC6900 SET LODCTRL(Mandatory)
LOD BTSSW(Optional)
BSC6900 LOD BTSPATCH(Optional)
BSC6900 SET FCCPUTHD(Optional)
BSC6900 SET FCMSGQTHD(Optional)
BSC6900 ADD SCTPLNK(Mandatory)
BSC6900 ADD SCTPLNK(Mandatory)
BSC6900 ADD SCTPLNK(Mandatory)
BSC6900 SET FCCPUTHD(Optional)
BSC6900 SET FCMSGQTHD(Optional)
BSC6900 SET FCSW(Optional)
BSC6900 COL LOG(Mandatory)
STR BTSLOG(Mandatory)
BSC6900 ULD BTSLOG(Mandatory)
BSC6900 SET GCELLLCS(Mandatory)
BSC6900 SET GCELLLCS(Mandatory)
BSC6900 SET GCELLLCS(Mandatory)
BSC6900 SET GCELLLCS(Mandatory)
BSC6900 SET GCELLLCS(Mandatory)
BSC6900 SET GCELLLCS(Mandatory)
BSC6900 ADD GPS(Mandatory)
BSC6900 ADD GPS(Mandatory)
BSC6900 STR BTSTST(Optional)
BSC6900 STR FRPORTLOOP(Mandatory)
BSC6900 SET E1T1(Optional)
BSC6900 LOP LAPDLNK(Mandatory)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 STR CALLRESLOP(Mandatory)
BSC6900 STR CALLRESLOP(Mandatory)
BSC6900 SET E1T1LOP(Mandatory)
BSC6900 SET OPTLOP(Mandatory)
BSC6900 STR CALLRESLOP(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET BTSFLEXABISPARA(Optional)
BSC6900 SET GCELLOTHBASIC(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 STR TRANSPERFTST(Mandatory)
BSC6900 ADD IPPATH(Mandatory)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET BTSIP(Mandatory)
BSC6900 ADD IPPATH(Mandatory)
BSC6900 ADD IPLOGICPORT(Mandatory)
BSC6900 SET GCELLEGPRSPARA(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET LDR(Optional)
BSC6900 EXP LOG(Optional)
BSC6900 CMP TBLDATA(Optional)
EXP BTSIPPARA(Optional)
BSC6900 EXP BTSVLAN(Optional)
BSC6900 LOD BRD(Optional)
BSC6900 SET LOGLIMIT(Mandatory)
BSC6900 EXP LOG(Mandatory)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 SET BTSEXD(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET DSPLVDSMODE(Mandatory)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET SCTPSRVPORT(Optional)
BSC6900 ADD XPUVLAN(Mandatory)
BSC6900 SET BTSETHPORT(Optional)
BSC6900 SET BTSETHPORT(Optional)
BSC6900 SET GCELLSOFT(Optional)
ADD ETHMA(Mandatory)
BSC6900 ADD ETHMEP(Mandatory)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 ADD BTSESN(Mandatory)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 ADD BTSBINDLOCGRP(Mandatory)
BSC6900 ADD BTS(Optional)
BSC6900 SET BTSAUTODLDACTINFO(Mandatory)
BSC6900 SET GCELLMAIOPLAN(Optional)
BSC6900 SET GCELLMAIOPLAN(Optional)
BSC6900 SET GCELLMAIOPLAN(Optional)
BSC6900 SET GCELLMAIOPLAN(Optional)
BSC6900 SET GCELLMAIOPLAN(Optional)
BSC6900 SET GCELLMAIOPLAN(Optional)
BSC6900 SET GCELLMAIOPLAN(Optional)
BSC6900 SET GCELLMAIOPLAN(Optional)
BSC6900 SET GCELLMAIOPLAN(Optional)
BSC6900 SET GCELLMAIOPLAN(Optional)
BSC6900 SET GCELLMAIOPLAN(Optional)
BSC6900 SET GCELLMAIOPLAN(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
ADD ETHMA(Mandatory)
BSC6900 PING BTSCFM(Mandatory)
ADD BTSETHMA(Mandatory)
BSC6900 ADD BTSETHLCMEP(Mandatory)
BSC6900 ADD PPPLNK(Mandatory)
BSC6900 ADD MPGRP(Mandatory)
ADD ETHIP(Mandatory)
BSC6900 ADD EMSIP(Mandatory)
BSC6900 ADD ICMPGUARD(Mandatory)
ADD IPRTBIND(Mandatory)
BSC6900 ADD ETHTRKIP(Mandatory)
BSC6900 ADD GCBSADDR(Mandatory)
SET BTSETHPORT(Optional)
BSC6900 IMP BTSDEVIP(Optional)
ADD BTSPPPLNK(Mandatory)
BSC6900 IMP BTSPPPLNK(Mandatory)
ADD BTSMPGRP(Mandatory)
BSC6900 IMP BTSMPGRP(Mandatory)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 SET BTSIPCLKPARA(Mandatory)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BTSBAKPWR(Optional)
ADD BTSAUTOPLAN(Mandatory)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 ADD IPMUX(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPGRP(Optional)
BSC6900 SET PWDPOLICY(Optional)
BSC6900 SET ALMCAPACITY(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GTRXBASE(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET PWDPOLICY(Optional)
BSC6900 SET BTSPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLPRACH(Optional)
BSC6900 SET GCELLPRACH(Optional)
BSC6900 SET GCELLPRACH(Optional)
BSC6900 SET GCELLPRACH(Optional)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPGRP(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLCCAD(Optional)
BSC6900 SET GCELLCCAD(Optional)
BSC6900 SET GCELLCCAD(Optional)
BSC6900 STR POSAVE(Optional)
BSC6900 SET GTRXBASE(Optional)
BSC6900 TRC IPADDR(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET PWDPOLICY(Optional)
BSC6900 ADD IPRTBIND(Mandatory)
BSC6900 STR IPCHK(Mandatory)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 COL SYNCINFO(Mandatory)
BSC6900 COL SYNCINFO(Mandatory)
ADD GCNOPERATOR(Mandatory)
BSC6900 ADD GCELL(Mandatory)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 ADD MPGRP(Optional)
ADD BTSMPGRP(Optional)
BSC6900 IMP BTSMPGRP(Optional)
ADD NCELL(Mandatory)
BSC6900 COL SYNCINFO(Mandatory)
ADD NCELL(Mandatory)
BSC6900 COL SYNCINFO(Mandatory)
SET BTSFMUABP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET BTSPSUFP(Optional)
ADD ETHMD(Mandatory)
BSC6900 ADD ETHMA(Mandatory)
BSC6900 ADD BTSETHMD(Optional)
ADD ETHMD(Mandatory)
BSC6900 PING BTSCFM(Mandatory)
ADD BTSETHMD(Mandatory)
BSC6900 ADD BTSETHMA(Mandatory)
BSC6900 SET GCELLPSI1(Optional)
BSC6900 ADD GNRNC(Mandatory)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 ADD ETHMEP(Mandatory)
ADD BTSETHLCMEP(Mandatory)
BSC6900 ADD BTSETHRMMEP(Mandatory)
BSC6900 ADD ETHMEP(Mandatory)
BSC6900 ADD MPGRP(Optional)
ADD BTSMPGRP(Optional)
BSC6900 IMP BTSMPGRP(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 ADD GEXT3GCELL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET GCELLHOCTRL(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 ADD GEXT3GCELL(Optional)
BSC6900 STR IPCHK(Optional)
BSC6900 ADD BTSBFD(Optional)
BSC6900 STR IPCHK(Optional)
BSC6900 ADD BTSBFD(Optional)
BSC6900 STR ETHMIRRORPORT(Mandatory)
BSC6900 STR ETHMIRRORPORT(Mandatory)
BSC6900 STR ETHMIRRORPORT(Mandatory)
ADD GCNOPERATOR(Mandatory)
BSC6900 ADD GCELL(Mandatory)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET CLKMODE(Mandatory)
BSC6900 ADD SCTPLNK(Mandatory)
BSC6900 SET QUICKCFG(Mandatory)
SWP MBSCMODE(Mandatory)
BSC6900 CHK MODEDATA(Mandatory)
BSC6900 SET GCSFILE(Mandatory)
BSC6900 SET MSP(Optional)
BSC6900 STR IPCHK(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 SET BTSDATUBP(Optional)
BSC6900 STR BTSRACKTEMPMON(Mandatory)
BSC6900 STR BTSRACKTEMPMON(Mandatory)
BSC6900 SET BTSAUTODLDACTINFO(Mandatory)
BSC6900 SET GCELLHOFAST(Optional)
ADD BTSMPGRP(Optional)
BSC6900 IMP BTSMPGRP(Optional)
ADD BTSMPGRP(Optional)
BSC6900 IMP BTSMPGRP(Optional)
ADD MPGRP(Mandatory)
BSC6900 ADD MPLNK(Mandatory)
BSC6900 ADD IPLOGICPORT(Optional)
ADD BTSMPGRP(Mandatory)
BSC6900 ADD BTSMPLNK(Mandatory)
BSC6900 ADD BTS(Optional)
SET BTSFMUABP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
ADD BTSMPGRP(Optional)
BSC6900 IMP BTSMPGRP(Optional)
BSC6900 ADD MPGRP(Optional)
SET MPUBIND(Mandatory)
BSC6900 ADD BRD(Mandatory)
SET MPUBIND(Mandatory)
BSC6900 ADD BRD(Mandatory)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLHOCTRL(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET GMRSCOPE(Mandatory)
BSC6900 SET GMRCTRL(Mandatory)
ADD BTSPPPLNK(Optional)
BSC6900 ADD BTSMPLNK(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 ADD GCNNODE(Optional)
BSC6900 ADD GCNOPERATOR(Mandatory)
BSC6900 ADD GCNOPERATOR(Optional)
BSC6900 ADD GCNOPERATOR(Optional)
BSC6900 ADD GCNNODE(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLTMR(Optional)
CHK INNSPCH(Mandatory)
BSC6900 STR CALLRESLOP(Mandatory)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET GCELLHOFAST(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET MSPCMD(Mandatory)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
SET BTSFMUABP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 ADD GEXT2GCELL(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET BSSGPPARA(Optional)
BSC6900 SET GBSCREDGRP(Optional)
BSC6900 SET GCELLSERVPARA(Optional)
BSC6900 SET SLFSLVSW(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 CHK E1T1CRS(Mandatory)
BSC6900 ADD MTP3LNK(Mandatory)
BSC6900 ADD GPS(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 SET ETHPORT(Optional)
BSC6900 SET BTSETHPORT(Optional)
BSC6900 SET BTSBAT(Optional)
BSC6900 SET GCELLSERVPARA(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPGRP(Optional)
BSC6900 ADD IPMUX(Mandatory)
BSC6900 SET BTSCABPARA(Optional)
BSC6900 STR IPCHK(Optional)
BSC6900 SET BTSRINGATTR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
SET
BSC6900 GCELLSTANDARDOPTPARA(Optional)
SET
BSC6900 GCELLSTANDARDOPTPARA(Optional)
SET
BSC6900 GCELLSTANDARDOPTPARA(Optional)
BSC6900 ADD BC(Optional)
BSC6900 ADD BC(Optional)
BSC6900 ADD BC(Optional)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 ADD OPC(Mandatory)
BSC6900 ADD N7DPC(Mandatory)
BSC6900 ADD MTP3RT(Mandatory)
BSC6900 ADD MTP3LKS(Mandatory)
BSC6900 ADD MTP3LNK(Mandatory)
BSC6900 ADD ADJNODE(Mandatory)
BSC6900 ADD M3LE(Mandatory)
BSC6900 ADD M3DE(Mandatory)
BSC6900 ADD M3RT(Mandatory)
BSC6900 ADD M3LKS(Mandatory)
BSC6900 ADD M3LNK(Mandatory)
BSC6900 ADD PCU(Mandatory)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLPSPWPARA(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 ADD GIBCAPNCGRP(Mandatory)
BSC6900 ADD GIBCAPNCGRP(Mandatory)
BSC6900 ADD GIBCAPNCGRP(Mandatory)
BSC6900 ADD GIBCAPNCGRP(Mandatory)
BSC6900 ADD G2GNCELL(Mandatory)
BSC6900 ADD G2GNCELL(Mandatory)
BSC6900 ADD G3GNCELL(Mandatory)
BSC6900 ADD G3GNCELL(Mandatory)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 ADD G2GNCELL(Mandatory)
BSC6900 ADD G2GNCELL(Mandatory)
BSC6900 ADD G2GNCELL(Mandatory)
BSC6900 ADD G2GNCELL(Mandatory)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLGPRS(Optional)
ADD GCELL(Optional)
BSC6900 ADD GEXT2GCELL(Mandatory)
BSC6900 ADD GCELLQUICKSETUP(Optional)
BSC6900 SET GCELLIDLEBASIC(Optional)
BSC6900 SET GCELLEXTMSRPARA(Optional)
BSC6900 SET GCELLHOFAST(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 ADD N7DPC(Optional)
BSC6900 ADD XPUVLAN(Mandatory)
BSC6900 SET GCELLHOCTRL(Optional)
BSC6900 ADD OMUIPRT(Mandatory)
BSC6900 ADD IPRT(Mandatory)
BSC6900 ADD IPRTBIND(Mandatory)
ADD BTSIPRT(Mandatory)
BSC6900 ADD BTSIPRTBIND(Mandatory)
BSC6900 ADD OPC(Mandatory)
BSC6900 DLD TCFILE(Mandatory)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET BTSALMPORT(Mandatory)
BSC6900 SET BTSALMPORT(Mandatory)
BSC6900 SET BTSALMPORT(Mandatory)
BSC6900 SET BTSALMPORT(Mandatory)
BSC6900 SET PWRPARA(Optional)
BSC6900 SET PWRPARA(Optional)
BSC6900 SET PWRPARA(Optional)
BSC6900 SET PWRPARA(Optional)
BSC6900 SET PWRPARA(Optional)
BSC6900 SET PWRPARA(Optional)
BSC6900 SET PWRPARA(Optional)
BSC6900 SET PWRPARA(Optional)
BSC6900 SET PWRPARA(Optional)
BSC6900 SET PWRPARA(Optional)
BSC6900 SET PWRPARA(Optional)
BSC6900 SET PWRPARA(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 ADD ADJNODE(Mandatory)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET BTSPMUBP(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLNWCTRLMSRPARA(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET BTSCABPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GTRXRLALM(Optional)
BSC6900 SET BTSFALLBACK(Optional)
BSC6900 TRC IPADDR(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 ADD NRIMSCMAP(Mandatory)
BSC6900 ADD NRISGSNMAP(Mandatory)
BSC6900 SET OTHSOFTPARA(Optional)
ADD NSE(Mandatory)
BSC6900 ADD NSVC(Mandatory)
BSC6900 ADD GCELLQUICKSETUP(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLLCS(Optional)
BSC6900 ADD NSVC(Mandatory)
ADD NSVC(Mandatory)
BSC6900 BLK NSVC(Mandatory)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET ETHPORT(Optional)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPGRP(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 ADD ETHTRK(Optional)
BSC6900 SET QUEUEMAP(Mandatory)
BSC6900 SET QUEUEMAP(Optional)
BSC6900 SET BTSANTANGLE(Mandatory)
BSC6900 STR TRXBURSTTST(Mandatory)
BSC6900 ADD GCSCHRUSER(Optional)
BSC6900 ADD GPSCHRUSER(Optional)
BSC6900 ADD OBJALMSHLD(Mandatory)
BSC6900 ADD BTSOBJALMSHLD(Mandatory)
BSC6900 SET FHO(Mandatory)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET BTSOMLBACKUP(Optional)
BSC6900 SET BTSOMLDETECT(Mandatory)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET BTSBWPARA(Mandatory)
BSC6900 SET BTSBWPARA(Mandatory)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET BSCSRVPRI(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET BTSLAPDWS(Optional)
BSC6900 ADD EMSIP(Optional)
BSC6900 ADD EMSIP(Optional)
EXP LOG(Optional)
BSC6900 ADD OP(Mandatory)
BSC6900 ADD GCELLOSPMAP(Mandatory)
BSC6900 ADD GCELLQUICKSETUP(Mandatory)
BLK ACIC(Mandatory)
BSC6900 ADD AE1T1(Mandatory)
BSC6900 ADD GCNOPERATOR(Mandatory)
BSC6900 ADD GCNOPERATOR(Mandatory)
BSC6900 ADD GCBSADDR(Mandatory)
BSC6900 UPD JTGCPLD(Mandatory)
BSC6900 BLK ACIC(Mandatory)
BSC6900 BLK ATERE1T1(Mandatory)
BSC6900 BLK AE1T1(Mandatory)
BSC6900 BLK PBCIC(Mandatory)
ADD GCNNODE(Mandatory)
BSC6900 ADD GCNOPERATOR(Mandatory)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SWP BTSBRD(Mandatory)
BSC6900 SET BTSFORBIDTS(Mandatory)
BSC6900 ADD GNRNC(Mandatory)
BSC6900 ADD BTSTOPCONFIG(Mandatory)
CON PATCH(Optional)
BSC6900 LOD PATCH(Optional)
BSC6900 ADD GCELLQUICKSETUP(Optional)
BSC6900 SET BTSOTHPARA(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLTMR(Optional)
BSC6900 SET GCELLTMR(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 ADD SEMILINK(Optional)
BSC6900 ADD SEMILINK(Mandatory)
BSC6900 ADD DXXTSEXGRELATION(Mandatory)
BSC6900 ADD DXXTSEXGRELATION(Mandatory)
BSC6900 SET BTSDTMUBP(Optional)
BSC6900 SET BTSDTMUBP(Optional)
BSC6900 SET BTSDTMUBP(Optional)
BSC6900 SET BTSDTMUBP(Optional)
BSC6900 ADD BTSLOCGRP(Mandatory)
BSC6900 ADD BTSLOCGRP(Mandatory)
BSC6900 ADD BTSLOCGRP(Optional)
BSC6900 SET GCELLHOEDBPARA(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 ADD SEMILINK(Mandatory)
BSC6900 ADD ABISLOADSHARE(Mandatory)
BSC6900 ADD SEMILINK(Mandatory)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 ADD GNRNC(Optional)
BSC6900 ADD SEMILINK(Mandatory)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET GCELLCCCH(Optional)
BSC6900 SET BTSCABPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BTSOTHPARA(Optional)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 SET BTSAUTODLDACTINFO(Mandatory)
BSC6900 SET BTSAUTODLDACTINFO(Mandatory)
BSC6900 ADD IPPATH(Optional)
BSC6900 ADD IPPATH(Mandatory)
ADD IPMUX(Mandatory)
BSC6900 ADD IPPATHBIND(Mandatory)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 ADD IPPATH(Optional)
CON PATCH(Optional)
BSC6900 LOD PATCH(Optional)
BSC6900 SET GCELLPSPWPARA(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLPSPWPARA(Optional)
BSC6900 BLK PBCIC(Mandatory)
BSC6900 ADD PCU(Mandatory)
BSC6900 ADD PBE1T1(Mandatory)
BSC6900 SET GCELLGPRS(Mandatory)
BSC6900 SET BTSFLEXABISPARA(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 ADD M3LKS(Optional)
BSC6900 SET GBSCREDGRP(Mandatory)
BSC6900 SET BTSIP(Mandatory)
BSC6900 SET BTSIP(Mandatory)
BSC6900 SET BTSIP(Mandatory)
BSC6900 SET BTSIP(Mandatory)
BSC6900 ADD PPPLNK(Mandatory)
BSC6900 ADD MPGRP(Mandatory)
BSC6900 STR IPCHK(Mandatory)
ADD BTSPPPLNK(Mandatory)
BSC6900 IMP BTSPPPLNK(Mandatory)
ADD BTSMPGRP(Mandatory)
BSC6900 IMP BTSMPGRP(Mandatory)
BSC6900 ADD SCTPLNK(Mandatory)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 ADD IPPATH(Mandatory)
BSC6900 ADD IPPATH(Optional)
BSC6900 ADD SCTPLNK(Mandatory)
BSC6900 SET BTSLOADCTRL(Mandatory)
BSC6900 SET GCELLHOCTRL(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 ADD IPPATH(Optional)
BSC6900 STR NCS(Mandatory)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPGRP(Optional)
ADD BTSPPPLNK(Optional)
BSC6900 ADD BTSMPGRP(Optional)
BSC6900 ADD NSE(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET PHBMAP(Mandatory)
BSC6900 ADD IPMUX(Mandatory)
BSC6900 SET GCELLIDLEBASIC(Optional)
BSC6900 SET CERTFILE(Optional)
BSC6900 STR ETHOAMLOOPTST(Optional)
BSC6900 STR ETHOAMLOOPTST(Optional)
BSC6900 STR FRPORTLOOP(Mandatory)
BSC6900 ADD BTSABISMUXFLOW(Optional)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 PING IP(Optional)
PING MAC(Optional)
BSC6900 PING BTSCFM(Optional)
BSC6900 SET GCELLPRACH(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 SET GCELLPRACH(Optional)
BSC6900 SET GCELLPRACH(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 SET GCELLPRACH(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET TCPLYVOICE(Mandatory)
BSC6900 SET TCPLYVOICE(Mandatory)
BSC6900 SET TCPLYVOICE(Optional)
BSC6900 SET FCCPUTHD(Optional)
BSC6900 SET FCMSGQTHD(Optional)
BSC6900 SET GCELLSOFT(Mandatory)
BSC6900 SET GCELLSOFT(Mandatory)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET FCCPUTHD(Optional)
BSC6900 SET FCMSGQTHD(Optional)
BSC6900 SET FCSW(Optional)
BSC6900 SET SCUPORT(Optional)
BSC6900 SET ALMPORT(Mandatory)
BSC6900 SET XPUPORT(Optional)
BSC6900 ADD ATERE1T1(Mandatory)
ADD AE1T1(Mandatory)
BSC6900 BLK AE1T1(Mandatory)
BSC6900 BLK ATERE1T1(Mandatory)
BSC6900 ADD PBE1T1(Mandatory)
BSC6900 ADD OBJALMSHLD(Mandatory)
SET MSPCMD(Mandatory)
BSC6900 SET MSP(Mandatory)
BSC6900 SET E1T1LOP(Optional)
LOP E1T1(Optional)
BSC6900 SET E1T1(Optional)
BSC6900 STR E1T1TST(Optional)
BSC6900 SET OPTLOP(Mandatory)
BSC6900 SWP ETHPORT(Mandatory)
BSC6900 SET OPT(Optional)
BSC6900 SET COPTLNK(Optional)
SET ETHPORT(Optional)
BSC6900 ADD ETHREDPORT(Mandatory)
BSC6900 ADD IPLOGICPORT(Optional)
STR IPCHK(Optional)
BSC6900 STR ETHOAMLOOPTST(Mandatory)
BSC6900 STR FRPORTLOOP(Optional)
BSC6900 CHK E1T1CRS(Mandatory)
BSC6900 ADD BC(Mandatory)
BSC6900 ADD PBSL(Mandatory)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
SET BTSENVALMPORT(Mandatory)
BSC6900 ADD BTSOBJALMSHLD(Mandatory)
SET BTSFORBIDTS(Mandatory)
BSC6900 ADD BTSPPPLNK(Mandatory)
BSC6900 SET BTSOMLTS(Mandatory)
BSC6900 ADD BTSCONNECT(Mandatory)
SET BTSETHPORT(Mandatory)
BSC6900 IMP BTSDEVIP(Mandatory)
BSC6900 ADD BTSETHLCMEP(Mandatory)
BSC6900 STR BTSTST(Optional)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 ADD ROLLBACKPOINT(Optional)
BEG ROLLBACK(Mandatory)
BSC6900 BEG FORWARD(Mandatory)
BSC6900 ADD FTPSCLTDPORT(Mandatory)
BSC6900 SWP BTSRING(Optional)
BSC6900 SWP BTSOMLLINK(Optional)
BSC6900 ADD DXXCONNECT(Mandatory)
BSC6900 ADD DXX(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Mandatory)
BSC6900 SET XPUPORT(Mandatory)
BSC6900 ADD ETHMEP(Mandatory)
BSC6900 ADD BTSTOPCONFIG(Mandatory)
BSC6900 SET GCELLCCUTRANSYS(Optional)
LOD BTSPATCH(Mandatory)
BSC6900 CON BTSPATCH(Mandatory)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 SET BTSPMUBP(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET BTSPMUBP(Optional)
BSC6900 SET BTSPOWERTYPE(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 SET GTRXDEV(Optional)
ADD BTSPPPLNK(Optional)
BSC6900 IMP BTSPPPLNK(Optional)
ADD BTSPPPLNK(Optional)
BSC6900 IMP BTSPPPLNK(Optional)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPLNK(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
ADD BTSPPPLNK(Mandatory)
BSC6900 ADD BTSMPLNK(Mandatory)
ADD PPPLNK(Optional)
BSC6900 ADD MPGRP(Optional)
BSC6900 ADD PORTFLOWCTRLPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLCCAD(Optional)
BSC6900 SET GMRCTRL(Optional)
ADD BTSIPRT(Optional)
BSC6900 IMP BTSIPRT(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET GCELLHOCTRL(Optional)
BSC6900 SET FCCPUTHD(Optional)
BSC6900 SET FCMSGQTHD(Optional)
BSC6900 SET FCCPUTHD(Optional)
BSC6900 SET FCMSGQTHD(Optional)
BSC6900 SET FCSW(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 ADD GEXT2GCELL(Optional)
BSC6900 SET BTSFLEXABISPARA(Optional)
BSC6900 SET GCELLSERVPARA(Optional)
ADD MTP3RT(Optional)
BSC6900 ADD M3RT(Optional)
ADD MTP3LNK(Optional)
BSC6900 ADD M3LNK(Optional)
BSC6900 ADD IPRT(Mandatory)
BSC6900 SET BTSOTHPARA(Mandatory)
BSC6900 SET BTSOTHPARA(Mandatory)
BSC6900 SET BTSOTHPARA(Mandatory)
BSC6900 SET CERTFILE(Optional)
BSC6900 SET BTSOTHPARA(Optional)
BSC6900 ADD N7DPC(Optional)
BSC6900 ADD BC(Optional)
BSC6900 SET BTSABISTROP(Optional)
BSC6900 SET GCELLDYNTURNOFF(Optional)
BSC6900 SET BSCDSTPA(Optional)
SET E1T1(Optional)
BSC6900 CHK E1T1CRS(Mandatory)
BSC6900 SET OPT(Optional)
BSC6900 SET COPTLNK(Mandatory)
BSC6900 SET GPSCHRCTRL(Optional)
BSC6900 SET GPSCHRCTRL(Optional)
BSC6900 SET GPSCHRCTRL(Optional)
BSC6900 SET GPSCHRCTRL(Optional)
BSC6900 SET GPSCHRCTRL(Optional)
BSC6900 ADD TRMFACTOR(Optional)
BSC6900 ADD TRMFACTOR(Optional)
BSC6900 ADD NSE(Optional)
BSC6900 ADD TRMMAP(Optional)
BSC6900 ADD TRMMAP(Optional)
BSC6900 ADD GCELL(Optional)
BSC6900 SET GCELLPSI1(Optional)
BSC6900 SET GCELLPSI1(Optional)
BSC6900 ADD TRMMAP(Optional)
BSC6900 ADD TRMMAP(Optional)
BSC6900 ADD GCELL(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GPSCHRCTRL(Optional)
BSC6900 SET GCELLCCACCESS(Optional)
BSC6900 ADD BTSLOCGRP(Optional)
BSC6900 SET GPSCHRCTRL(Mandatory)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET BTSOTHPARA(Optional)
BSC6900 SET SLFSLVSW(Optional)
BSC6900 SET ALMPORT(Mandatory)
BSC6900 ADD SNTPSRVINFO(Mandatory)
BSC6900 SET GCELLIDLEAD(Optional)
BSC6900 ADD NSE(Mandatory)
BSC6900 SET BTSENVALMPORT(Optional)
BSC6900 SET E1T1(Optional)
BSC6900 SET E1T1(Optional)
BSC6900 SET E1T1(Optional)
BSC6900 SET E1T1(Optional)
ADD BTSABISHDLCPATH(Mandatory)
BSC6900 ADD BTSBIND2HDLCPATH(Mandatory)
BSC6900 SET ETHPORT(Mandatory)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET CERTFILE(Optional)
BSC6900 SET BTSAUTODLDACTINFO(Optional)
LOD BTSPATCH(Mandatory)
BSC6900 CON BTSPATCH(Mandatory)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET CERTFILE(Mandatory)
ADD OP(Mandatory)
BSC6900 DLD LICENSE(Mandatory)
DLD RETANTCFG(Mandatory)
BSC6900 ULD BTSDEVFILE(Mandatory)
BSC6900 SET PWDPOLICY(Optional)
BSC6900 STR BTSTST(Mandatory)
BSC6900 SET PWRALMSW(Optional)
BSC6900 SET PWRALMSW(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLCCACCESS(Optional)
BSC6900 SET GCELLCCACCESS(Optional)
BSC6900 SET GCELLSOFT(Optional)
ADD BTSBRDCAP(Mandatory)
BSC6900 ADD BTSRXUBRD(Optional)
BSC6900 SET BTSBAKPWR(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET QUEUEMAP(Optional)
BSC6900 SET QUEUEMAP(Optional)
BSC6900 SET QUEUEMAP(Optional)
BSC6900 SET QUEUEMAP(Optional)
BSC6900 SET QUEUEMAP(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLPSOTHERPARA(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET BTSAIRCON(Optional)
BSC6900 SET BTSAIRCON(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET BTSAUXEQP(Optional)
BSC6900 SET BTSBAT(Optional)
BSC6900 SET BTSBAT(Mandatory)
BSC6900 SET BTSBAT(Mandatory)
BSC6900 SET BTSBAT(Mandatory)
BSC6900 SET BTSAUXEQP(Optional)
BSC6900 SET BTSBAT(Optional)
BSC6900 SET BTSBAT(Mandatory)
BSC6900 SET BTSBAT(Mandatory)
BSC6900 SET BTSBAT(Mandatory)
BSC6900 SET BTSAUXEQP(Optional)
BSC6900 SET BTSBAT(Optional)
BSC6900 SET BTSBAT(Mandatory)
BSC6900 SET BTSBAT(Mandatory)
BSC6900 SET BTSBAT(Mandatory)
BSC6900 ADD GEXT2GCELL(Optional)
BSC6900 ADD GEXT3GCELL(Optional)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 ADD GCELLQUICKSETUP(Optional)
BSC6900 SET BTSAUTOPLANCFG(Optional)
BSC6900 SET GCELLCCACCESS(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET GCELLCCCH(Optional)
BSC6900 ADD BTSLOCGRP(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET GCELLRESELECTPARA(Optional)
BSC6900 SET GCELLCCACCESS(Optional)
BSC6900 SET GCELLRESELECTPARA(Optional)
BSC6900 SET BTSETHPORT(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GMRCTRL(Optional)
BSC6900 BEG FORWARD(Mandatory)
BSC6900 RUN BATCHFILE(Optional)
ADD BTSRXUCHAIN(Mandatory)
BSC6900 SET BTSBREAKPOINT(Mandatory)
BSC6900 CBN BTSRXUCHAIN(Mandatory)
BSC6900 CBN BTSRXUCHAIN(Mandatory)
BSC6900 SET GTRXDEV(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET GCELLCCAD(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 ADD BRD(Mandatory)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET CLK(Optional)
BSC6900 SET CLK(Optional)
BSC6900 SET CLK(Optional)
BSC6900 SET CLK(Optional)
BSC6900 SET CLK(Optional)
BSC6900 SET CLK(Optional)
BSC6900 SET CLK(Optional)
BSC6900 SET BTSLSW(Optional)
SET
BSC6900 GREDGRPPRIMHOSTPOLICY(Mandatory)
SET
BSC6900 GREDGRPPRIMHOSTPOLICY(Mandatory)
SET
BSC6900 GREDGRPPRIMHOSTPOLICY(Mandatory)
BSC6900 ADD AISSCFG(Mandatory)
BSC6900 SET BTSRXUBP(Mandatory)
BSC6900 SET BTSDFCUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Mandatory)
BSC6900 SET BTSRXUBP(Mandatory)
BSC6900 SET BTSDFCUBP(Optional)
ADD TRMMAP(Optional)
BSC6900 ADD TRMFACTOR(Mandatory)
BSC6900 ADD IPRT(Mandatory)
BSC6900 ADD NSVLREMOTE(Mandatory)
BSC6900 ADD GSMSCB(Mandatory)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET BTSENVALMPORT(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET PWDPOLICY(Optional)
BSC6900 SET BSCNSPARA(Optional)
BSC6900 SET BTSOTHPARA(Optional)
BSC6900 SET BSCNSPARA(Optional)
BSC6900 TST SNDRSI(Mandatory)
BSC6900 SET OTHSOFTPARA(Optional)
DLD LICENSE(Optional)
BSC6900 ULD LICENSE(Optional)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPLNK(Optional)
EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 ADD GNRNC(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLCCCH(Optional)
BSC6900 ADD SUBTSK(Optional)
BSC6900 ADD BTS(Optional)
BSC6900 SET BTSDGPSBP(Optional)
BSC6900 ADD NSE(Optional)
BSC6900 SET E1T1LOP(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 ADD GEXT3GCELL(Mandatory)
BSC6900 ADD GEXT3GCELL(Optional)
ADD GNRNC(Mandatory)
BSC6900 ADD GIURGCONN(Mandatory)
BSC6900 ADD GNRNC(Mandatory)
BSC6900 SET CERTFILE(Optional)
BSC6900 ADD SGSNROUTEINFO(Mandatory)
BSC6900 ADD SGSNROUTEINFO(Mandatory)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLNWCTRLMSRPARA(Optional)
BSC6900 SET GCELLNWCTRLMSRPARA(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET GCELLOTHBASIC(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 ADD IPPATH(Mandatory)
BSC6900 ADD RSCGRP(Mandatory)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 ADD G3GNCELL(Optional)
BSC6900 ADD GEXT3GCELL(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET GCELLNCRESELECTPARA(Optional)
BSC6900 SET BTSBWPARA(Mandatory)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET BTSBWPARA(Mandatory)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 SET BTSLAPDWS(Optional)
BSC6900 LCK CMCTRL(Mandatory)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 UPD JTGCPLD(Mandatory)
BSC6900 RUN BATCHFILE(Optional)
BSC6900 ADD OPC(Optional)
ADD BTSPPPLNK(Optional)
BSC6900 ADD BTSMPLNK(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 SET TRANSPATCHPARA(Optional)
BSC6900 SET TRANSPATCHPARA(Optional)
BSC6900 SET TRANSPATCHPARA(Optional)
BSC6900 SET TRANSPATCHPARA(Optional)
BSC6900 SET TRANSPATCHPARA(Optional)
BSC6900 SET TRANSPATCHPARA(Optional)
BSC6900 SET TRANSPATCHPARA(Optional)
BSC6900 SET TRANSPATCHPARA(Optional)
BSC6900 SET TRANSPATCHPARA(Optional)
BSC6900 SET TRANSPATCHPARA(Optional)
BSC6900 SET BSCDSTPA(Optional)
BSC6900 SET MSP(Optional)
ADD M3LE(Optional)
BSC6900 ADD M3DE(Optional)
BSC6900 ADD GCNNODE(Optional)
BSC6900 ADD GCNNODE(Optional)
BSC6900 ADD OMUIPRT(Mandatory)
BSC6900 ADD OMUIPRT(Mandatory)
ADD BTSIPRT(Optional)
BSC6900 IMP BTSIPRT(Mandatory)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLPSCHM(Optional)
ADD BTSIPRT(Mandatory)
BSC6900 IMP BTSIPRT(Mandatory)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET BTSAUTODLDACTINFO(Mandatory)
BSC6900 ADD IPPATH(Mandatory)
BSC6900 ADD RSCGRP(Mandatory)
BSC6900 SET GCELLSERVPARA(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 ADD TRXBIND2PHYBRD(Mandatory)
BSC6900 SET BTSRXUBP(Mandatory)
BSC6900 ADD BTSRXUBRD(Mandatory)
BSC6900 ADD TRXBIND2PHYBRD(Mandatory)
BSC6900 SET BTSRXUBP(Mandatory)
BSC6900 ADD TRXBIND2PHYBRD(Mandatory)
BSC6900 SET BTSRXUBP(Mandatory)
BSC6900 ADD BTSRXUBRD(Mandatory)
BSC6900 ADD TRXBIND2PHYBRD(Mandatory)
BSC6900 SET BTSRXUBP(Mandatory)
BSC6900 ADD BTSRXUBRD(Mandatory)
BSC6900 SET BTSRXUBP(Mandatory)
BSC6900 SET OPT(Optional)
BSC6900 SET OPT(Optional)
BSC6900 SET BTSDEMUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 ADD GCNNODE(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET GCELLDYNTURNOFF(Mandatory)
BSC6900 SET GCELLDYNTURNOFF(Mandatory)
BSC6900 SET GCELLDYNTURNOFF(Optional)
BSC6900 SET GCELLDYNTURNOFF(Optional)
BSC6900 SET GCELLDYNTURNOFF(Mandatory)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDEMUBP(Optional)
BSC6900 SET BTSDEMUBP(Optional)
BSC6900 SET BTSDOMUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 COL SYNCINFO(Mandatory)
BSC6900 COL SYNCINFO(Mandatory)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET BSCPSTCDSCPMAP(Optional)
BSC6900 SET GCELLHOFAST(Optional)
ADD NCELL(Mandatory)
BSC6900 COL SYNCINFO(Mandatory)
ADD NCELL(Mandatory)
BSC6900 COL SYNCINFO(Mandatory)
SET GCELLSBC(Optional)
BSC6900 ADD GSMSCB(Mandatory)
BSC6900 STR BTSTST(Optional)
ADD SUBTSK(Mandatory)
BSC6900 ADD SUBCMD(Mandatory)
BSC6900 SET GMRSCOPE(Mandatory)
BSC6900 ADD SRCONPATH(Optional)
ADD GEXT3GCELL(Mandatory)
BSC6900 SET GCELLHOFDDBA2(Mandatory)
EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
ADD SCTPLNK(Mandatory)
BSC6900 ADD M3LNK(Mandatory)
BSC6900 ADD SUBTSK(Mandatory)
BSC6900 EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 SET ALMCAPACITY(Optional)
BSC6900 SET MSP(Optional)
BSC6900 STR BTSLOG(Optional)
BSC6900 SET TZ(Mandatory)
BSC6900 ADD GCELLQUICKSETUP(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET MSP(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 SET GCELLHOCTRL(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 ADD GEXT2GCELL(Optional)
BSC6900 ADD GEXT2GCELL(Optional)
BSC6900 SET BSCPSTCDSCPMAP(Optional)
BSC6900 SET MSP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 ADD BTSALMMGMRULE(Mandatory)
BSC6900 ADD BTSALMMGMRULE(Mandatory)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET BTSLOADCTRL(Mandatory)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Mandatory)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET AITFOTHPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET BTSOTHPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SPT BTSRXUCHAIN(Mandatory)
BSC6900 ADD BTS(Optional)
BSC6900 SET FTPSSRV(Mandatory)
BSC6900 SET FTPSSRV(Mandatory)
BSC6900 ADD BTSRETANT(Mandatory)
BSC6900 ADD FTPSCLTDPORT(Mandatory)
BSC6900 SET BSCBASIC(Optional)
BSC6900 ADD BTS(Optional)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 EXP LOG(Optional)
SET BTSVLAN(Mandatory)
BSC6900 IMP BTSVLAN(Mandatory)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 ADD BTSSFPMODE(Mandatory)
BSC6900 ADD SGSNNODE(Optional)
BSC6900 ADD SGSN(Mandatory)
BSC6900 ADD GCNOPERATOR(Mandatory)
BSC6900 ADD GCNOPERATOR(Optional)
BSC6900 ADD GCNOPERATOR(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 ADD SGSNNODE(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 ADD ABISLOADSHARE(Mandatory)
BSC6900 SET BTSSHARING(Optional)
BSC6900 SET ALMSHLD(Mandatory)
BSC6900 SET BTSBAKPWR(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 ADD AISSCFG(Optional)
ADD MTP3RT(Mandatory)
BSC6900 ADD MTP3LKS(Mandatory)
ADD M3RT(Mandatory)
BSC6900 ADD M3LKS(Mandatory)
BSC6900 ADD M3LNK(Mandatory)
BSC6900 ADD NSVLLOCAL(Optional)
BSC6900 ADD NSVLREMOTE(Optional)
BSC6900 SET BSCSRVPRI(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 ADD MTP3LNK(Mandatory)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 PING IP(Mandatory)
BSC6900 TRC IPADDR(Optional)
BSC6900 COL LOG(Optional)
BSC6900 SET BTSAISS(Mandatory)
BSC6900 SET BTSIPCLKPARA(Mandatory)
BSC6900 ADD BTSBINDLOCGRP(Mandatory)
BSC6900 STR TRANSPERFTST(Mandatory)
BSC6900 ADD N7DPC(Optional)
BSC6900 SET GBSCREDGRP(Optional)
BSC6900 SET TZ(Mandatory)
BSC6900 ADD GEXTSMLC(Mandatory)
BSC6900 ADD GEXTSMLC(Mandatory)
BSC6900 ADD EMU(Optional)
BSC6900 SET TZ(Mandatory)
SET FCCPUTHD(Optional)
BSC6900 SET FCMSGQTHD(Optional)
SWP BRD(Mandatory)
BSC6900 STR BKP(Mandatory)
BSC6900 DLD TCFILE(Mandatory)
ADD MTP3LNK(Optional)
BSC6900 ADD SCTPLNK(Mandatory)
BSC6900 ADD M3LNK(Mandatory)
SET PHBMAP(Mandatory)
BSC6900 ADD ATERE1T1(Mandatory)
BSC6900 BLK ATERE1T1(Mandatory)
BLK AE1T1(Mandatory)
BSC6900 ADD PBE1T1(Mandatory)
EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 ADD OBJALMSHLD(Optional)
SET E1T1LOP(Mandatory)
BSC6900 LOP E1T1(Mandatory)
SWP ETHPORT(Mandatory)
BSC6900 ADD ETHREDPORT(Mandatory)
ADD GCBSADDR(Mandatory)
BSC6900 SET TCPLYVOICE(Mandatory)
BSC6900 ADD GIURGCONN(Mandatory)
ADD TRXBIND2PHYBRD(Mandatory)
BSC6900 SWP BTSRING(Optional)
ADD BTSBFD(Optional)
BSC6900 ADD BTSIPRTBIND(Optional)
BSC6900 ADD NSE(Mandatory)
BSC6900 ADD PBSL(Mandatory)
ADD BTSSFPMODE(Optional)
BSC6900 SET BTSFORBIDTS(Optional)
BSC6900 ADD BTSCONNECT(Mandatory)
BSC6900 OPR BTSBRDPWR(Mandatory)
BSC6900 SET GTRXDEV(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET SNTPCLTPARA(Mandatory)
BSC6900 ADD OPC(Optional)
BSC6900 ADD OPC(Mandatory)
BSC6900 ADD OPC(Optional)
BSC6900 ADD PBE1T1(Mandatory)
ADD OPC(Optional)
BSC6900 ADD N7DPC(Optional)
BSC6900 SET GCELLCCBASIC(Optional)
BSC6900 SET BTSFMUABP(Optional)
BSC6900 SET BTSFMUABP(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET BTSCHNFALLBACK(Mandatory)
BSC6900 SET BTSCHNFALLBACK(Mandatory)
BSC6900 SET BTSCHNFALLBACK(Mandatory)
BSC6900 SET ETHPORT(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 ADD GCNOPERATOR(Optional)
BSC6900 ADD GNRNC(Optional)
BSC6900 ADD GNRNC(Optional)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 ADD GCNNODE(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET FTPSCLT(Optional)
ADD OPC(Mandatory)
BSC6900 ADD N7DPC(Mandatory)
BSC6900 ADD BTS(Mandatory)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 ADD BTSCABINET(Optional)
ADD G2GNCELL(Mandatory)
BSC6900 ADD GIBCAPNCGRP(Mandatory)
ADD G2GNCELL(Mandatory)
BSC6900 ADD GIBCAPNCGRP(Mandatory)
BSC6900 ADD G3GNCELL(Mandatory)
BSC6900 ADD G3GNCELL(Mandatory)
BSC6900 ADD G2GNCELL(Mandatory)
BSC6900 RUN BATCHFILE(Mandatory)
BSC6900 SET CLKMODE(Mandatory)
BSC6900 ADD CLKSRC(Mandatory)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 ADD BTSBFD(Mandatory)
BSC6900 ADD G2GNCELL(Mandatory)
BSC6900 ADD G2GNCELL(Mandatory)
PING MAC(Mandatory)
BSC6900 TRC MAC(Mandatory)
BSC6900 ADD G2GNCELL(Mandatory)
BSC6900 ADD TSCROSS(Mandatory)
BSC6900 ADD CLKSRC(Mandatory)
BSC6900 ADD TSCROSS(Mandatory)
SWP BRD(Mandatory)
BSC6900 STR BKP(Mandatory)
ADD SUBRACK(Mandatory)
BSC6900 SET CLK(Mandatory)
ADD MTP3LNK(Optional)
BSC6900 ADD SCTPLNK(Mandatory)
ADD RSCGRP(Mandatory)
BSC6900 SET PHBMAP(Mandatory)
BSC6900 ADD M3LNK(Mandatory)
BSC6900 BLK ATERE1T1(Mandatory)
BSC6900 COL LOG(Optional)
EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
ADD ETHMD(Mandatory)
BSC6900 ADD ETHTRK(Mandatory)
ADD GCBSADDR(Mandatory)
BSC6900 SET TCPLYVOICE(Mandatory)
BSC6900 ADD GIURGCONN(Mandatory)
ADD TRXBIND2PHYBRD(Mandatory)
BSC6900 SWP BTSRING(Optional)
ADD BTSBFD(Optional)
BSC6900 ADD BTSIPRTBIND(Optional)
BSC6900 ADD NSE(Mandatory)
BSC6900 ADD PBSL(Mandatory)
ADD BTSSFPMODE(Optional)
BSC6900 SET BTSFORBIDTS(Optional)
BSC6900 ADD BTSCONNECT(Mandatory)
BSC6900 OPR BTSBRDPWR(Mandatory)
BSC6900 ADD SRCONPATH(Mandatory)
BSC6900 ADD SRCONPATH(Mandatory)
BSC6900 ADD SUBRACK(Mandatory)
BSC6900 SET BTSTMA(Mandatory)
BSC6900 SET CLK(Mandatory)
BSC6900 EXP ALMLOG(Optional)
BSC6900 ADD NSVLLOCAL(Optional)
BSC6900 ADD NSVLREMOTE(Optional)
BSC6900 SET BTSPSUFP(Optional)
BSC6900 ADD BTSABISMUXFLOW(Mandatory)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET CPUTHD(Optional)
BSC6900 SET CPUTHD(Optional)
BSC6900 SET CPUTHD(Optional)
BSC6900 SET CPUTHD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
STR BKP(Optional)
BSC6900 ULD RSTINFO(Mandatory)
BSC6900 ADD GIURGCONN(Mandatory)
BSC6900 EXP ALMLOG(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET TZ(Mandatory)
BSC6900 EXP LOG(Optional)
BSC6900 ADD SUBTSK(Mandatory)
BSC6900 COL LOG(Optional)
BSC6900 EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 ADD GSMSCB(Mandatory)
EXP ALMLOG(Optional)
BSC6900 STA ALMLOG(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 BLK ACIC(Mandatory)
BSC6900 BLK PBCIC(Mandatory)
BSC6900 ADD BSCDSTPADATE(Mandatory)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 ADD BSCDSTPADATE(Mandatory)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BTSFORBIDTS(Optional)
BSC6900 SET BTSFALLBACK(Optional)
BSC6900 SET BSCDSTPA(Optional)
BSC6900 BLK ATERE1T1(Mandatory)
BSC6900 BLK AE1T1(Mandatory)
BSC6900 SET BTSFORBIDTS(Mandatory)
BSC6900 SET BTSFMUABP(Optional)
BSC6900 SET BTSNFCBBP(Optional)
BSC6900 ADD AE1T1(Mandatory)
BSC6900 ADD BTSMONITORTS(Optional)
BSC6900 ADD OP(Mandatory)
BSC6900 STR NCS(Mandatory)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 STR BTSLOG(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET BTSFALLBACK(Optional)
BSC6900 ADD N7DPC(Optional)
BSC6900 ADD BTSMONITORTS(Mandatory)
BSC6900 SET GCELLFREQSCAN(Optional)
BSC6900 ADD BTSMONITORTS(Optional)
BSC6900 ADD BTSMONITORTS(Optional)
BSC6900 ADD BTSMONITORTS(Mandatory)
BSC6900 ADD OP(Mandatory)
BSC6900 ADD BTSMONITORTS(Mandatory)
BSC6900 SET BTSAUTODLDACTINFO(Optional)
BSC6900 BLK ACIC(Mandatory)
BSC6900 ADD AE1T1(Mandatory)
BSC6900 STR BTSLOG(Optional)
BSC6900 ADD IPMUX(Optional)
BSC6900 ADD BTSABISMUXFLOW(Optional)
ADD SUBTSK(Mandatory)
BSC6900 ADD SUBCMD(Mandatory)
BSC6900 SET SUBNET(Mandatory)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET BTSFLEXABISPARA(Optional)
BSC6900 SET BTSOMLTS(Mandatory)
BSC6900 SET BTSAUTODLDACTINFO(Mandatory)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET CLK(Optional)
BSC6900 SET CLK(Optional)
BSC6900 SET GCELLSBC(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLGPRS(Optional)
BSC6900 SET BSSLS(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 ADD GNRNC(Optional)
BSC6900 SET GCELLPRACH(Optional)
BSC6900 ADD NSE(Mandatory)
BSC6900 ADD NSE(Mandatory)
BSC6900 SET ALMPORT(Optional)
BSC6900 SET ASWPARA(Mandatory)
BSC6900 SET OBJAUTHSW(Mandatory)
BSC6900 SET BTSENVALMPORT(Mandatory)
BSC6900 OPR BTSBRDPWR(Mandatory)
BSC6900 SET TZ(Mandatory)
BSC6900 SET SCUPORT(Mandatory)
BSC6900 SET SLFSLVSW(Mandatory)
BSC6900 SET LICENSECTRL(Mandatory)
BSC6900 SET BFDPROTOSW(Mandatory)
BSC6900 SET BTSALMPORT(Mandatory)
BSC6900 SET BTSETHPORT(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 SET SS7PATCHSWITCH(Optional)
BSC6900 SET SS7PATCHSWITCH(Optional)
BSC6900 SET SS7PATCHSWITCH(Optional)
BSC6900 SET SS7PATCHSWITCH(Optional)
BSC6900 SET SS7PATCHSWITCH(Optional)
BSC6900 SET SS7PATCHSWITCH(Optional)
BSC6900 SET SS7PATCHSWITCH(Optional)
BSC6900 SET SS7PATCHSWITCH(Optional)
BSC6900 SET SS7PATCHSWITCH(Optional)
BSC6900 SET SS7PATCHSWITCH(Optional)
BSC6900 ADD BTSSFPMODE(Optional)
BSC6900 SET OPSW(Mandatory)
BSC6900 SET TZ(Mandatory)
BSC6900 SET BTSAISS(Optional)
BSC6900 ADD GEXT3GCELL(Mandatory)
BSC6900 SET BTSOTHPARA(Optional)
BSC6900 SET BTSIPCLKPARA(Mandatory)
BSC6900 SET BTSIPCLKPARA(Optional)
BSC6900 SET BTSIPCLKPARA(Optional)
BSC6900 SET BTSIPCLKPARA(Optional)
BSC6900 SET SYS(Optional)
BSC6900 SET SYS(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET SYS(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET SYS(Optional)
BSC6900 SET SYS(Optional)
BSC6900 SET BSSGPPARA(Optional)
BSC6900 CHG BTSPTUSHKTM(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET BSSGPPARA(Optional)
BSC6900 CHG BTSPTUSHKTM(Optional)
BSC6900 SET BTSRINGATTR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET GCELLCCTMR(Optional)
BSC6900 SET BTSRINGATTR(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET BSSGPPARA(Optional)
BSC6900 CHG BTSPTUSHKTM(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET GCELLPSBASE(Optional)
BSC6900 SET GCELLIDLEBASIC(Optional)
BSC6900 ADD BC(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET BSSGPPARA(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET BSSGPPARA(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET BSSGPPARA(Optional)
BSC6900 SET BSSGPPARA(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
ADD AISSCFG(Mandatory)
BSC6900 ADD NCELL(Mandatory)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLPSPWPARA(Optional)
BSC6900 SET GCELLPSPWPARA(Optional)
BSC6900 EXP DEVFILE(Optional)
BSC6900 EXP BTSDEVFILE(Optional)
BSC6900 SET BTSOMLBACKUP(Optional)
BSC6900 SET BTSRINGATTR(Optional)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 SET BSSGPPARA(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET GCELLHOCTRL(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 ADD MTP3LNK(Optional)
BSC6900 ADD MTP3LNK(Mandatory)
BSC6900 SET GCELLSOFT(Optional)
ADD BTSRXUCHAIN(Mandatory)
BSC6900 CBN BTSRXUCHAIN(Mandatory)
BSC6900 ADD ATERCONPATH(Mandatory)
BSC6900 SET BSCBASIC(Mandatory)
BSC6900 ADD ATERCONPATH(Mandatory)
BSC6900 ADD ATERCONPATH(Mandatory)
BSC6900 SET TCTYPE(Mandatory)
BSC6900 SET GCELLIDLETDDBA1(Mandatory)
BSC6900 SET GCELLHOTDDBA2(Mandatory)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLIDLETDDBA1(Mandatory)
BSC6900 SET GCELLIDLETDDBA1(Mandatory)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 SET GCELLCCUTRANSYS(Optional)
BSC6900 ADD GEXT3GCELL(Optional)
BSC6900 SET GCELLIDLETDDBA1(Mandatory)
BSC6900 SET GCELLHOTDDBA2(Mandatory)
BSC6900 SET GCELLCCUTRANSYS(Optional)
SET GCELLIDLETDDBA1(Mandatory)
BSC6900 SET GCELLHOTDDBA2(Mandatory)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD TRMLOADTH(Optional)
BSC6900 ADD SRCONPATH(Mandatory)
BSC6900 ADD SRCONPATH(Mandatory)
BSC6900 ADD PBSL(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SAV GCELLTEMPLATE(Optional)
BSC6900 EXP GCELLTEMPLATE(Mandatory)
BSC6900 SAV GCELLTEMPLATE(Optional)
ADD GCELL(Optional)
BSC6900 ADD BTSAUTOPLAN(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDPMUBP(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET BSCNSPARA(Optional)
BSC6900 ADD GSMSCB(Mandatory)
BSC6900 SET TCPARA(Optional)
BSC6900 STR BTSVSWRTST(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SWP OMUAREA(Mandatory)
BSC6900 ADD TGWIP(Mandatory)
BSC6900 ADD TGWIP(Mandatory)
BSC6900 ADD TGWIP(Mandatory)
BSC6900 ADD TGWIP(Mandatory)
BSC6900 ADD TGWIP(Mandatory)
BSC6900 SET BSSGPPARA(Optional)
BSC6900 SET BTSAIRCON(Optional)
BSC6900 SET BTSAIRCON(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 ADD TRMLOADTH(Mandatory)
BSC6900 SET BSCTMR(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 SET GCELLCHMGBASIC(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 ADD GCNOPERATOR(Optional)
BSC6900 ADD OP(Optional)
BSC6900 SET TIME(Optional)
BSC6900 SET GCELLFREQSCAN(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 PING IP(Optional)
BSC6900 TRC IPADDR(Optional)
PING MAC(Optional)
BSC6900 PING BTSCFM(Optional)
TRC MAC(Optional)
BSC6900 TRC BTSCFM(Optional)
BSC6900 ADD BTSABISMUXFLOW(Optional)
ADD GEXT2GCELL(Optional)
BSC6900 SET GCELLHOFAST(Optional)
BSC6900 PING IP(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLTMR(Optional)
BSC6900 ADD GCNOPERATOR(Optional)
BSC6900 SET LOGLIMIT(Optional)
SET MSTOCELL(Mandatory)
BSC6900 TST SNDRSI(Mandatory)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 ADD SUBTSK(Mandatory)
BSC6900 ADD SUBTSK(Mandatory)
BSC6900 ADD SUBTSK(Optional)
BSC6900 ADD SUBTSK(Optional)
BSC6900 ADD SUBTSK(Optional)
BSC6900 ADD SUBTSK(Optional)
BSC6900 ADD TRMMAP(Mandatory)
BSC6900 ADD ADJMAP(Mandatory)
BSC6900 STR FRPORTLOOP(Mandatory)
BSC6900 STR BTSVSWRTST(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET ALMBLKPARA(Optional)
CHK INNSPCH(Mandatory)
BSC6900 STR CALLRESLOP(Mandatory)
BSC6900 SET ALMBLKPARA(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 SET MTP3TMR(Optional)
BSC6900 CMP TBLDATA(Optional)
ADD ATERSL(Optional)
BSC6900 ADD ATERCONSL(Optional)
BSC6900 ADD PBE1T1(Optional)
BSC6900 SET TZ(Mandatory)
BSC6900 SET GCELLIDLEAD(Optional)
BSC6900 ADD BTSTOPCONFIG(Optional)
BSC6900 ADD BTSTOPCONFIG(Mandatory)
BSC6900 ADD BTSTOPCONFIG(Optional)
BSC6900 COL FAMLOG(Mandatory)
ADD BTSRXUCHAIN(Mandatory)
BSC6900 CBN BTSRXUCHAIN(Mandatory)
BSC6900 SET GCELLTMR(Optional)
BSC6900 SET FCCPUTHD(Optional)
BSC6900 SET FCMSGQTHD(Optional)
BSC6900 SET FCCPUTHD(Optional)
BSC6900 SET FCMSGQTHD(Optional)
BSC6900 SET FCSW(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 ADD M3LKS(Optional)
BSC6900 SET BTSTRANS(Mandatory)
BSC6900 ADD ABISLOADSHARE(Mandatory)
BSC6900 ADD IPPATH(Optional)
BSC6900 ADD TRMMAP(Optional)
BSC6900 ADD TRMLOADTH(Mandatory)
BSC6900 SET BSCABISPRIMAP(Mandatory)
BSC6900 SET BTSBWPARA(Mandatory)
BSC6900 SET BTSDOMUBP(Optional)
BSC6900 SET BTSDOMUBP(Optional)
BSC6900 SET BTSDOMUBP(Optional)
BSC6900 SET BTSDOMUBP(Optional)
BSC6900 SET BTSCLKPARA(Mandatory)
BSC6900 SET GCELLRESELECTPARA(Optional)
BSC6900 SET GCELLHOAD(Optional)
BSC6900 ADD ETHTRKLNK(Mandatory)
BSC6900 ADD ETHTRKLNK(Mandatory)
ADD ETHTRK(Mandatory)
BSC6900 ADD ETHTRKLNK(Mandatory)
BSC6900 SET BSCABISPRIMAP(Mandatory)
BSC6900 ADD IPPATH(Optional)
BSC6900 ADD RSCGRP(Optional)
BSC6900 ADD TRMLOADTH(Mandatory)
BSC6900 ADD PPPLNK(Optional)
BSC6900 ADD MPGRP(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET BSCABISPRIMAP(Mandatory)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 STR IPCHK(Optional)
BSC6900 ADD ETHMEP(Mandatory)
BSC6900 SET GCELLCCACCESS(Optional)
BSC6900 STR BTSTST(Mandatory)
BSC6900 SET GTRXCHANHOP(Optional)
SET FHO(Mandatory)
BSC6900 SET GTRXCHANHOP(Mandatory)
BSC6900 ADD BTSBINDLOCGRP(Mandatory)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
BSC6900 ADD GCELLHOPANTGRP(Optional)
SET GCELLHOPQUICKSETUP(Optional)
BSC6900 SET
BSC6900 STR TRXPERFTST(Mandatory)
BSC6900 SET GTRXCHANHOP(Optional)
BSC6900 ADD GTRX(Optional)
ADD BTSBRDCAP(Mandatory)
BSC6900 ADD BTSRXUBRD(Optional)
BSC6900 ADD TRXBIND2PHYBRD(Mandatory)
BSC6900 ADD BTSBINDLOCGRP(Mandatory)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 ADD TRXBIND2PHYBRD(Mandatory)
BSC6900 BLK ATERE1T1(Mandatory)
BSC6900 BLK AE1T1(Mandatory)
LOP E1T1(Mandatory)
BSC6900 STR E1T1TST(Optional)
BSC6900 ADD BC(Mandatory)
BSC6900 SET BTSOMLTS(Mandatory)
BSC6900 ADD PPPLNK(Mandatory)
BSC6900 ADD MPLNK(Mandatory)
ADD BTSPPPLNK(Mandatory)
BSC6900 ADD BTSMPLNK(Mandatory)
BSC6900 ADD GCELLMAGRP(Optional)
BSC6900 SET BTSIDLETS(Mandatory)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 ADD TSCROSS(Optional)
BSC6900 STR TRANSPERFTST(Mandatory)
BSC6900 ADD BTSMONITORTS(Optional)
ADD SCHTSK(Mandatory)
BSC6900 SET SCHTSKSW(Optional)
BSC6900 ADD ATEROML(Mandatory)
ADD BTSABISHDLCPATH(Mandatory)
BSC6900 ADD BTSTOPCONFIG(Mandatory)
ADD BTSRXUCHAIN(Mandatory)
BSC6900 CBN BTSRXUCHAIN(Mandatory)
BSC6900 ADD PBSL(Mandatory)
BSC6900 SET GTRXCHAN(Optional)
BSC6900 SET GTRXDEV(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 ADD BTSMONITORTS(Mandatory)
ADD BTSRXUCHAIN(Mandatory)
BSC6900 CBN BTSRXUCHAIN(Mandatory)
BSC6900 STR BTSTST(Mandatory)
BSC6900 STR TRANSPERFTST(Mandatory)
BSC6900 STR BTSBATTTST(Mandatory)
BSC6900 STR BTSRFTST(Mandatory)
BSC6900 SET BSCDSTPA(Optional)
BSC6900 ADD BTSRXUCHAIN(Mandatory)
BSC6900 PING IP(Optional)
TRC MAC(Optional)
BSC6900 TRC BTSCFM(Optional)
BSC6900 SET GCELLDYNTURNOFF(Optional)
BSC6900 SET GCELLDYNTURNOFF(Optional)
BSC6900 SET GCELLDYNTURNOFF(Optional)
BSC6900 SET GCELLDYNTURNOFF(Mandatory)
BSC6900 SET GCELLDYNTURNOFF(Optional)
BSC6900 SET BTSAPMUBP(Optional)
BSC6900 SET BTSDHEUBP(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 ADD AISSCFG(Optional)
BSC6900 SET GCELLIDLEBASIC(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 ADD IPPATH(Mandatory)
BSC6900 ADD RSCGRP(Mandatory)
BSC6900 PING IP(Optional)
BSC6900 SET GCELLPRACH(Optional)
BSC6900 ADD SUBRACK(Mandatory)
BSC6900 RUN BATCHFILE(Mandatory)
BSC6900 ADD GCELL(Mandatory)
BSC6900 SET BSCPCUTYPE(Mandatory)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 ADD BTSCABINET(Optional)
BSC6900 ADD GCELLQUICKSETUP(Mandatory)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET BTSANTFEEDERCONNECT(Optional)
BSC6900 SET CSABISCONGCTRL(Optional)
BSC6900 SET CSABISCONGCTRL(Optional)
BSC6900 SET CSABISCONGCTRL(Optional)
BSC6900 SET CSABISCONGCTRL(Optional)
BSC6900 SET CSABISCONGCTRL(Optional)
BSC6900 SET CSABISCONGCTRL(Optional)
BSC6900 SET CSABISCONGCTRL(Optional)
BSC6900 SET CSABISCONGCTRL(Optional)
BSC6900 SET CSABISCONGCTRL(Optional)
BSC6900 SET CSABISCONGCTRL(Optional)
BSC6900 SET CSABISCONGCTRL(Optional)
BSC6900 SET MSGSOFTPARA(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 SET PSPREFABISCONGCTRL(Optional)
BSC6900 SET PSPREFABISCONGCTRL(Optional)
BSC6900 SET PSPREFABISCONGCTRL(Optional)
BSC6900 SET PSPREFABISCONGCTRL(Optional)
BSC6900 SET PSPREFABISCONGCTRL(Optional)
BSC6900 SET PSPREFABISCONGCTRL(Optional)
BSC6900 SET PSPREFABISCONGCTRL(Optional)
BSC6900 SET PSPREFABISCONGCTRL(Optional)
BSC6900 SET PSPREFABISCONGCTRL(Optional)
BSC6900 SET PSPREFABISCONGCTRL(Optional)
BSC6900 SET PSPREFABISCONGCTRL(Optional)
BSC6900 SET AITFOTHPARA(Optional)
BSC6900 ADD IPMUX(Mandatory)
BSC6900 ADD IPMUX(Mandatory)
BSC6900 ADD NSVLLOCAL(Mandatory)
BSC6900 ADD NSVLREMOTE(Mandatory)
BSC6900 ADD OP(Optional)
BSC6900 SET BTSEXD(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 STR E1T1TST(Optional)
BSC6900 SET ALMPORT(Optional)
BSC6900 SET BTSENVALMPORT(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 ADD G2GNCELL(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLTMR(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLHOBASIC(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLHOINTERRATLDB(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLPWR2(Optional)
BSC6900 SET GCELLHOEMG(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLAMRQUL(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWR3(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLPWRBASIC(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLCCAMR(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET BSCPSSOFTPARA(Optional)
BSC6900 SET GCELLSOFT(Optional)
BSC6900 SET GCELLHOFITPEN(Optional)
BSC6900 SET BSCBASIC(Optional)
BSC6900 SET E1T1(Optional)
BSC6900 SET BSCNSPARA(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 ADD BTSCONNECT(Mandatory)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 ADD BTSCONNECT(Mandatory)
BSC6900 ADD BTSAUTOPLAN(Mandatory)
BSC6900 ADD BTSCONNECT(Mandatory)
BSC6900 ADD GSMSCB(Mandatory)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLEGPRSPARA(Optional)
BSC6900 SET GCELLPSCHM(Optional)
BSC6900 SET GCELLEGPRSPARA(Optional)
BSC6900 SET GCELLEGPRSPARA(Optional)
BSC6900 SET GCELLPRIVATEOPTPARA(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLEGPRSPARA(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET BTSFALLBACK(Optional)
BSC6900 SET BTSLAPDWS(Optional)
BSC6900 SET GCELLBASICPARA(Optional)
BSC6900 ADD RSCGRP(Mandatory)
BSC6900 ADD IPLOGICPORT(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 SET GCELLCCAD(Optional)
BSC6900 SET GCELLPRIVATEOPTPARA(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLPSCS(Optional)
BSC6900 SET GCELLNC2PARA(Optional)
CHK INNSPCH(Mandatory)
BSC6900 STR CALLRESLOP(Mandatory)
BSC6900 SET BSCPSSOFTPARA(Optional)
DLD LICENSE(Mandatory)
BSC6900 ULD LICENSE(Mandatory)
DLD RETANTCFG(Mandatory)
BSC6900 ULD BTSDEVFILE(Mandatory)
BSC6900 SET BTSDOMUBP(Mandatory)
BSC6900 SET BTSDOMUBP(Mandatory)
BSC6900 SET BTSEXD(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 SET GCELLHOIUO(Optional)
BSC6900 ADD GEXT3GCELL(Mandatory)
BSC6900 ADD BTSRETANT(Mandatory)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET GCELLGSMR(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 ADD GCELL(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 SET BSCFCPARA(Optional)
BSC6900 ADD IPPATH(Optional)
BSC6900 SET BSCABISPRIMAP(Optional)
BSC6900 ADD SCTPLNK(Optional)
BSC6900 ADD SCTPLNK(Optional)
ADD IPPATH(Mandatory)
BSC6900 ADD VLANID(Mandatory)
BSC6900 ADD ETHMA(Mandatory)
SET BTSVLAN(Optional)
BSC6900 IMP BTSVLAN(Optional)
BSC6900 ADD BTSETHMA(Mandatory)
BSC6900 ADD SCTPLNK(Mandatory)
BSC6900 ADD SCTPLNK(Mandatory)
BSC6900 SET DSCPMAP(Optional)
SET BTSVLAN(Optional)
BSC6900 IMP BTSVLAN(Optional)
SET BTSVLAN(Optional)
BSC6900 IMP BTSVLAN(Optional)
BSC6900 SET GCELLCCACCESS(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 SET BTSDFCUBP(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
SET BTSDFCUBP(Optional)
BSC6900 SET BTSDDPUBP(Optional)
SET BTSDFCUBP(Optional)
BSC6900 SET BTSDDPUBP(Optional)
SET BTSDFCUBP(Optional)
BSC6900 SET BTSDDPUBP(Optional)
BSC6900 SET GCELLOTHEXT(Optional)
BSC6900 SET BTSAUTODLDACTINFO(Mandatory)
BSC6900 SET GCELLTMR(Optional)
BSC6900 SET GCELLTMR(Optional)
BSC6900 SET GCELLTMR(Optional)
BSC6900 ADD GEXTSMLC(Optional)
BSC6900 SET GCELLTMR(Optional)
BSC6900 SET GCELLCHMGAD(Optional)
BSC6900 ADD GEXTSMLC(Optional)
BSC6900 SET BTSOUTPUT(Optional)
BSC6900 ADD EMU(Optional)
BSC6900 ADD OP(Optional)
BSC6900 SET GCELLLCS(Optional)
BSC6900 SET BTSOUTPUT(Optional)
BSC6900 STR IPCHK(Optional)
BSC6900 SET OTHSOFTPARA(Optional)
BSC6900 ADD OP(Mandatory)
BSC6900 ADD M3LKS(Optional)
BSC6900 SET GTRXRLALM(Optional)
BSC6900 SET GTRXRLALM(Optional)
BSC6900 SET GTRXRLALM(Optional)
BSC6900 SET GTRXRLALM(Optional)
BSC6900 SET GTRXRLALM(Mandatory)
BSC6900 FMT DATA(Optional)
BSC6900 SET BTSRXUBP(Optional)
BSC6900 ADD SUBRACK(Mandatory)
BSC6900 SET E1T1(Optional)
BSC6900 ADD BTS(Optional)
ADD ATERSL(Optional)
BSC6900 ADD ATERCONSL(Optional)
BSC6900 SET BTSOMLBACKUP(Optional)
BSC6900 SET BTSRINGATTR(Optional)
BSC6900 SET MSP(Optional)
BSC6900 SET TZ(Optional)
Meaning
Downlink quality level threshold for the MS to be assigned with a channel of the better cell.
Uplink quality level threshold for the MS to be assigned with a channel of the better cell.
The maximum duration for the BSC to select the best cell according to MRs in the MS assigning procedure. The BSC
assigns the channel of the serving cell to the MS if the best cell is not selected within the duration specified by this
Whether to enable the BTS to support bypass function. HDLC BTS and IP BTS do not support this parameter.
Whether to permit Abis flow control.
The flow control function helps in better call management. If congestion occurs, the system lightens its load by
Used along with "Abis Flow Control Timer 2" to control the change in cell flow control levels.When the flow control
level in the cell changes, the values of MS MAX Retrans and Tx-integer in the system information are changed
Used along with "Abis Flow Control Timer 1" to control the change in cell flow control levels.When the flow control
level in the cell changes, the values of MS MAX Retrans and Tx-integer in the system information are changed
This parameter controls the strategy for idle timeslot selection and optimization by the PS channels.
This parameter controls whether the strategy for timeslot configuration and optimization is started. When this
parameter is set to ON, the bundled idle timeslots for the PS channel should be allocated to the same 64 kbit/s
Threshold for enabling the BTS local switching. When the congestion rate at the Abis interface exceeds this
threshold, the BTS local switching is enabled.
This parameter specifies whether to enable the Abis resource adjustment TCHH function.
It specifies whether the TCHH is preferentially allocated to the MS by the BSC6900, when Abis resources are
Interval between detection of the Abis timeslot being in idle state and releasing of the Abis timeslot. When channels
are idle, the timer is started. When the timer is expires, the Abis timeslot is released. When all the TBFs on the
Phase tag for GSM protocols that the Abis interface supports
Duration available for the BTS to collect the AB after the TRX or channel is activated.
Mean opinion score (threshold) for judging an abnormal call. The BTS computes the MOS of a call periodically and
reports the call MOS to the BSC in custom measurement reports. According to the call MOS, the BSC checks
Access pulse type of the PRACH, uplink PTCCH and packet control acknowledge message of the MS.
8bit: 8 bit pulse access mode; 11bit: 11 bit pulse access mode.
Access control class of the MS
When the cell supports Repeated This parameter specifies whether the access control function is enabled in a cell.
When the function is enabled, the BSC determines which MSs in the cell to be connected to the network by sending
This parameter specifies the index of the access control policy that is used in a cell.
Subcell preferred during the incoming inter-BSC handover to the concentric cell. In the case of incoming inter-BSC
handover to the concentric cell, the channels in this subcell are preferred.
This parameter specifies the index of an access control (ACC) policy. It is used to identify an ACC policy.
Whether the initial service is uplink, downlink or neutral
This parameter is used to specify the starting point of the ACC sliding window in an access control policy.
This parameter is used to specify the ACC sliding window size in an access control policy. MSs of the ACC access
classes that are specified in the sliding window are not allowed to access the network.
This parameter is used to specify the sliding speed of the ACC sliding window in an access control policy.
Whether to compress the address and control fields. If this parameter is set to ENABLE, the address and control
area compression is enabled. If this parameter is set to DISABLE, the address and control area compression is
A flag bit indicates Whether to support the compression of the address and control fields.
This parameter specifies whether to receive the CS paging request from A interface when the MS uses a PS service.
This parameter is used to control the paging collaboration function of A interface of the entire BSC. This parameter
Used for notifying MSs where to retrieve relevant parameters during cell reselection.
The default value of this parameter is 0 in system message 3 and, has no special significance.
Active coding set (ACS)[F], indicates a set of full-rate coding rates currently available for calls. The AMR is a set of
multiple speech coding and decoding rates.
Active coding set (ACS)[H], indicates set of half-rate coding rates currently available for calls. The AMR is a set of
multiple speech coding and decoding rates.
Active coding set (ACS)[WB], indicates a set of wide-band coding rates currently available for calls. The AMR is a set
of multiple speech coding and decoding rates.
Whether to activate the function of L2 re-establishment. If this function is activated, the BSC starts the attempt of L2
re-establishment when the BSC receives an ERR IND message reported by the BTS in a conversation of MSs. If the
Valid duration of the reserved TRX or timeslot
AC voltage alarm lower threshold. When the input AC voltage is lower than the value of this parameter, an alarm
indicating the abnormal AC is reported.
The BTS reports an alarm if the AC voltage exceeds the value of this parameter.
The BTS reports an alarm if the AC voltage is lower than the value of this parameter.
The BTS reports an alarm if the AC voltage exceeds the value of the AC voltage alarm upper threshold. When the
input AC voltage is higher than the value of this parameter, an alarm indicating the abnormal AC is reported.
Whether to hand over an MS to another channel during an intra-cell handover through the assignment process
Communication address of the CBUS3 on the bus 485. The configuration of this parameter must be consistent with
the actual physical connection. Otherwise, the board may not work properly.
Interval for requesting the bandwidth for the secondary link when the system is not in congestion state
Bandwidth requested each time for the secondary link when the system is not in congestion state
Whether to enable each AC RRU external alarm port's customer definition switch.
"0" indicates that the external alarm port's customer definition switch is disabled and
The destination signaling point (DSP) of the adjacent BSC must be an Iur-g DSP.
Whether to adjust the BTS offset manually or automatically
Mode of dynamically adjusting the EGPRS uplink encoding scheme.
Value 0 indicates dynamic adjustment of EGPRS uplink coding scheme is not supported;
This parameter specifies whether to enable automatic auto-loading and auto-activation of the BTS software. If this
parameter is set to Yes, the BTS software is automatically loaded and activated when the BTS is initialized or a
This parameter specifies the automatic load mode of the BTS software. If this parameter is set to common download,
common loading is performed on the OML/EML, and the link is not extended. If this parameter is set to quick
Administrative state of a cell
Administrative state of the TRX
Administrative state of the channel
End time for adjusting the offset time
Cell load threshold for adjusting the offset time. If the load threshold is exceeded, the offset time is not adjusted.
Offset Time Adjustment Switch
Start time for adjusting the offset time
Advanced alarm management rule type
This parameter specifies the software version 1 that is automatically loaded and activated. The version of the BTS
software stored on the OMU must be consistent with this version number. Otherwise, a software version
This parameter specifies the software version 2 that is automatically loaded and activated. The BTS software stored
on the OMU must be consistent with this version number. Otherwise, the software version inconsistency alarm may
If the echo path is traced, the echo is judged and controlled according to the trace result of the echo path
parameters. Otherwise, the echo is judged and controlled according to the recommended value.
This parameter is used for echo judgment and control when the echo parameters are not traced.
If the local input voltage is lower than the value of this parameter and the remote end transmits the voice signal, the
AEC function uses the comfort noise to replace the minor echo. In this case, the speech signals at low level may also
Extra delay due to the transmission line. This parameter should be set according to the actual conditions and is
applicable to satellite transmission.
This parameter is used to determine whether there are speech signals at the local end. If the local SNR is lower than
the value of this parameter, echo control is not performed.
This parameter indicates whether the acoustic echo cancellation (AEC) functional switch is on or off.
Threshold for detecting the AEC performance
Time for detecting the AEC performance
Counter for radio link failures during an AMR full rate call. See the description of "Radio Link Timeout" in "SET
GCELLCCBASIC".
Number of SACCH multiframes during an AMR full rate call. See the description of "SACCH Multi-Frames" in "SET
GCELLCCBASIC".
GPS receiver ID
GPS receiver type.
Counter for radio link failures during an AMR half rate call. See the description of "Radio Link Timeout" in "SET
GCELLCCBASIC".
Number of SACCH multiframes during an AMR half rate call. See the description of "SACCH Multi-Frames" in "SET
GCELLCCBASIC".
Alarm ID
Alarm ID
Identifier of the alarm. This parameter uniquely identifies an alarm.
Identifier of the alarm. This parameter uniquely identifies an alarm.
Identifier of the alarm. This parameter uniquely identifies an alarm.
Alarm ID
Alarm ID
Delay time for mutual-aid detection on a cell after the cell is initialized. When the cell initialization has just finished,
the cell is in an unstable state. Mutual-aid detection at this time may cause a wrong decision. Therefore, this
Type of alarm selection
Alarm selection mode
Whether to trace A-interface messages during end-to-end user tracing. The end-to-end tracing is conducted
throughout the network. The A-interface tracing results can be obtained from the MSC or BSC.
Whether to allow flow control for the location update services during the A interface flow control
whether to allow flow control for the mobile-originated services during the A interface flow control
Whether to allow flow control for the mobile-terminated services during the A interface flow control
Whether to allow flow control for the other services including emergency call, call re-establish, and LMU services
during the A interface flow control
Whether to enable the A interface flow control mechanism in the BSC6900
Flow control method used by the BSC6900. Flow control method at the Abis interface: When receiving a channel
request message, the BSC6900 begins flow control on the call according to the flow control level of the A interface.
Rate of discarded services in level 1 of the A interface flow control
Rate of discarded services in level 2 of the A interface flow control
Rate of discarded services in level 3 of the A interface flow control
Rate of discarded services in level 4 of the A interface flow control
Rate of discarded services in level 5 of the A interface flow control
Rate of discarded services in level 6 of the A interface flow control
CSD(Circuit Switched Data) service redundancy level, which is configured to decrease the data loss rate during
transmission in A over IP mode.
Fixed gain value in fixed gain mode
Target level in fixed level mode
This parameter restrains the maximum gain to the input signal. It is valid only when "ALC Mode" is "FIXEDLEVEL" or
"ADAPTIVE". If the parameter is set to a small value, it may affect the conformance to the target level.
Maximum target level in adaptive ALC mode
Mimumum target level in adaptive ALC mode
ALC level control mode
Whether to enable the adaptive level control (ALC) function
Retry times after the timer for the reply from the peer expires during the NSVC live test. If the reply is not received
after the system resends the message according to retry times, the NSVC is regarded as faulty.
Duration of the timer to wait for the reply from the peer during the NSVC live test
Specifies the bandwidth occupied when the " transmission resource group type " is IP and the " bandwidth mode " is
HALF_DUPLEX.
Whether to reassign the TBF for a different Trx
When this parameter is set to ON, the GMM/SM signaling service is assigned only one PDCH; otherwise, the
GMM/SM signaling service is assigned one or more PDCHs as required.
Maximum ratio of the number of AMR half rate channels to the total number of channels in a cell. When the resource
allocation principle is determined by the BSC, no AMR half rate channel can be further assigned if the ratio of the
Whether to allow EDA multiplex. "Not Allow": the TBF of the EDA cannot be multiplexed with other TBR; "Allow": the
TBF of the EDA can be multiplexed with other TBF.
Number of allowed measure report missed. If the number of allowed measure report missed exceeds this value, the
previous measure report is invalid.
Maximum ratio of the number of half rate channels to the total number of channels in a cell. When the resource
allocation principle is determined by the BSC, no half rate channel can be further assigned if the ratio of the number
Value ALLCIC indicates that all E1/T1 timeslots on the A interface must be set with the start CIC. Value ALLNULL
indicates that all E1/T1 timeslots on the A interface can be set with the value NULL.
Value ALLCIC indicates that all E1/T1 timeslots on the PB interface must be set with the start CIC. Value ALLNULL
indicates that all E1/T1 timeslots on the PB interface can be set with the value NULL.
If the feed current of the TMA on tributary 0 is smaller than the value of this parameter, the TMA Low Temperature
alarm is triggered.
If the feed current of the TMA on tributary 1 is smaller than the value of this parameter, the TMA Low Temperature
alarm is triggered.
If the feed current of the TMA on tributary 2 is smaller than the value of this parameter, the TMA Low Temperature
alarm is triggered.
If the feed current of the TMA on tributary 3 is smaller than the value of this parameter, the TMA Low Temperature
alarm is triggered.
If the feed current of the TMA on tributary 4 is smaller than the value of this parameter, the TMA Low Temperature
alarm is triggered.
If the feed current of the TMA on tributary 5 is smaller than the value of this parameter, the TMA Low Temperature
alarm is triggered.
Accumulated alarm clearance failure duration.Threshold for the accumulated duration in which the alarm persists. If
the accumulated duration exceeds this threshold, an alarm is cleared. Otherwise, the alarm persists.
Whether the configuration of alarm parameters is allowed.
In multi-mode scenario, the value of this parameter must be the same as the value of the parameter in other modes.
ID of the intermittent alarm.
Alarm ID
If the input current of the antenna feeder is smaller than the value of this parameter, an alarm related to the GPS
antenna is reported.
If the input current of the antenna feeder is greater than the value of this parameter and "GPS or RGPS" is set to
"GPS", an alarm related to the GPS antenna is reported.
If the input current of the antenna feeder is greater than the value of this parameter and "GPS or RGPS" is set to
"RGPS", an alarm related to the RGPS antenna is reported.
Accumulated alarm occurrence duration.Threshold for the accumulated duration in which the alarm persists. If the
accumulated duration exceeds this threshold, an alarm is generated. Otherwise, no alarm is generated.
Alarm Occur Accumulative Time refers to the percentage of the alarm occurrence accumulative time to "Flash Statis
Alarm Raise Time Window". If the alarm occurrence accumulative duration is greater than the parameter value, the
Alarm Clear Accumulative Time refers to the percentage of the alarm clearance accumulative time to "Flash Statis
Alarm Clear Time Window". If the alarm clearance accumulative duration is greater than this threshold, the BTS fault
If the number of alarm flashes exceeds the value of this parameter within the time specified by "Flash Statis Alarm
Raise Time Window", the BTS Statistical Alarm is generated. If this parameter is set to 0, the statistics of the BTS
If the number of alarm flashes is smaller than the value of this parameter within the time specified by "Flash Statis
Alarm Clear Time Window", the BTS Statistical Alarm is cleared. If this parameter is set to 0, the statistics of the BTS
Whether the configuration of alarm parameters is allowed. The value "YES" indicates that the configuration is
allowed, and the value "NO" indicates that the configuration is not allowed.
Type of the alarm. The alarm can be a fault alarm or an event alarm.
It is used to perform open loop power control. Alpha parameter is used by the MS to calculate the output power PCH
of the uplink PDCH. This parameter is used to set the reduced class of the Tx power of the MS, in correspondence
Decimal part of the antenna altitude
Height of the specified GSP receiver antenna
Integer part of the antenna altitude
Height of the specified GSP receiver antenna
Alarm severity. One or more severities can be selected. By default, all severities are selected.
Alarm severity. One or more severities can be selected. By default, all severities are selected.
Whether to supply power to the TMA on tributary 0
Whether to supply power to the TMA on tributary 1
Whether to supply power to the TMA on tributary 2
Whether to supply power to the TMA on tributary 3
Whether to supply power to the TMA on tributary 4
Whether to supply power to the TMA on tributary 5
Maximum degree by which the BSC can control the power of the AMR BTS dynamically
Whether to enable the III power control algorithm for AMR calls. If enabled, power control is performed on AMR calls.
Whether to enable the adaptive adjustment function of AMR downlink threshold. After this function is enabled, the
BTS estimates the long-term voice quality (indicated by the long-term FER(frame erase ratio)) and compares the
Number of measurement reports sampled for averaging downlink AMR signal strength. A single measurement report
may not reflect the actual network situations accurately. Therefore, the BSC needs to average the measured values
Number of downlink AMR measurement reports that the BSC predicts. The BSC takes a while to confirm the power
control effect of a power control command. Thus, the BSC makes a power control decision based on a measurement
Quality level threshold for decreasing downlink AMR signal power. If the BTS transmits AMR signals at a quality level
less than "AMR DL Qual. Upper Threshold", the BSC decreases the power of the BTS. If (downlink receive level -
Quality level threshold for increasing downlink AMR signal power. If the BTS transmits AMR signals at a quality level
greater than "AMR DL Qual. Lower Threshold", the BSC increases the power of the BTS. If (downlink receive level +
Number of measurement reports sampled for averaging downlink AMR signal quality. A single measurement report
may not reflect the actual network situations accurately. Therefore, the BSC needs to average the measured values
During downlink power control, if the downlink receive quality level is equal to or greater than this threshold, "AMR
DL RX_LEV Upper Threshold" is increased by "AMR DL Qual Bad UpLEVDiff" to further increase the expected
During downlink power control, if the downlink receive quality level is equal to or greater than "AMR DL Qual Bad
Trig Threshold", "AMR DL RX_LEV Upper Threshold" is increased by "AMR DL Qual Bad UpLEVDiff" to further
Upper threshold for downlink AMR signal strength.
If the downlink received AMR signal level is greater than this threshold, a power decrease is computed. Then, the
Lower threshold for downlink AMR signal strength.
If the downlink received AMR signal level is less than this threshold, a power increase is computed. Then, the power
Whether to enable the algorithm for the load-based AMR handover between full rate and half rate
With "F-H Ho Period" and the duration for triggering handover from full rate to half rate, this parameter determines
the current ATCB offset by which to choose the MSs to undergo handover from full rate to half rate.
ATCB threshold for the AMR handover from full rate to half rate. If the ATCB of an AMR full rate call is equal to or
greater than this threshold, the AMR call is handed over from full rate to half rate.
With "F-H Ho Period" and the duration for triggering handover from full rate to half rate, this parameter determines
the current path loss offset by which to choose the MSs to undergo handover from full rate to half rate.
Path loss threshold for the AMR handover from full rate to half rate. If the path loss of an AMR full rate call is equal to
or less than this threshold, the AMR call is handed over from full rate to half rate.
Quality threshold for the AMR handover from full rate to half rate. If the uplink and downlink receive quality levels of
an AMR full rate call are equal to or less than this threshold, the AMR call is handed over from full rate to half rate.
Load threshold for the AMR handover from full rate to half rate. If the cell load is greater than this threshold, the AMR
full rate calls are handed over to half rate.
ATCB threshold for the AMR handover from half rate to full rate. If the ATCB of an AMR half rate call is less than this
threshold, the AMR call is handed over from half rate to full rate.
Path loss threshold for the AMR handover from half rate to full rate. If the path loss of an AMR half rate call is greater
than this threshold, the AMR call is handed over from half rate to full rate.
Whether to enable the algorithm for the uplink and downlink receive quality based AMR handover from half rate to
full rate
Quality threshold for the AMR handover from half rate to full rate. If the receive quality level of an AMR half rate call
is greater than this threshold, the AMR call is handed over from half rate to full rate.
Load threshold for the AMR handover from half rate to full rate. If the cell load is less than this threshold, the AMR
half rate calls are handed over to full rate.
Maximum step by which the power can be increased according to received signal quality
Maximum step by which the power can be decreased when the received signal quality belongs to quality zone 0.
Huawei power control algorithm generation II classifies the received signal quality into three quality zones. The
Maximum step by which the power can be decreased when the received signal quality belongs to quality zone 1.
Huawei power control algorithm generation II classifies the received signal quality into three quality zones. The
Maximum step by which the power can be decreased when the received signal quality belongs to quality zone 2.
Huawei power control algorithm generation II classifies the received signal quality into three quality zones. The
Maximum step by which the power can be increased according to received signal level
Whether to enable the compensation of AMR measurement reports in Huawei power control algorithm generation II
If this parameter is set to YES, Huawei power control algorithm generation II puts a currently received measurement
Minimum interval between two consecutive AMR power control commands
Maximum step by which the power can be decreased according to received signal quality
Number of levels by which the BTS increases the power of an SACCH frame. This parameter is used for SACCH
power control. When sending an SACCH frame, the BTS increases the power of the SACCH frame by this specified
Whether to enable the BSC to assign AMR half rate channels preferentially according to the channel types allowed
by the MSC and the current TCH seizure ratio of the cell
Load threshold for assigning half rate channels preferentially. If the current TCH seizure ratio of the cell is greater
than this threshold, AMR half rate channels are assigned preferentially.
Whether to enable the adaptive adjustment function of AMR uplink threshold. After this function is enabled, the BTS
estimates the long-term voice quality (indicated by the long-term FER(frame erase rate)) and compares the
Number of measurement reports sampled for averaging uplink AMR signal strength. A single measurement report
may not reflect the actual network situations accurately. Therefore, the BSC needs to average the measured values
Number of uplink AMR measurement reports that the BSC predicts. The BSC takes a while to confirm the power
control effect of a power control command. Thus, the BSC makes a power control decision based on a measurement
Quality level threshold for decreasing the power of an uplink AMR call. If the MS transmits AMR signals at a quality
level less than "AMR ULQual. Upper Threshold", the BTS decreases the power of the MS. If (uplink receive level -
Quality level threshold for increasing the power of an uplink AMR call. If the MS transmits AMR signals at a quality
level greater than "AMR UL Qual. Lower Threshold", the BTS increases the power of the MS. If (uplink receive level
Number of measurement reports sampled for averaging uplink AMR signal quality. A single measurement report may
not reflect the actual network situations accurately. Therefore, the BSC needs to average the measured values in
During uplink power control, if the uplink receive quality level is equal to or greater than this threshold, "AMR UL
RX_LEV Upper Threshold" is increased by "AMR UL Qual. Bad UpLEVDiff" to further increase the expected uplink
During uplink power control, if the uplink receive quality level is equal to or greater than "AMR UL Qual. Bad Trig
Threshold", "AMR UL RX_LEV Upper Threshold" is increased by "AMR UL Qual. Bad UpLEVDiff" to further increase
Upper threshold for uplink AMR signal strength
If the uplink received AMR signal level is greater than this threshold, a power decrease is computed. Then, the power
Lower threshold for uplink AMR signal strength.
If the uplink received AMR signal level is less than this threshold, a power increase is computed. Then, the power is
Maximum number of retransmissions of the A-interface circuit reset message. When an A-interface circuit of the BSC
is reset, the BSC sends the reset message to the MSC and starts a timer. If the BSC fails to receive the A-interface
Maximum number of times of resending a reset message at the A interface. When the BSC6900 is reset, the
BSC6900 sends a reset message to the MSC and starts a timer. If the timer expires when the BSC6900 waits for a
Maximum gain to the signals from the remote end. If the parameter is set to a small value, the target SNR may be
restrained when the signal arrives at the local end.
Whether to enable the adaptive noise cancel (ANC) function
The system adjusts the remote input so that the ratio of the remote signal to the local noise is above the value of this
parameter.
Tilt angle of the RET antenna, it is accurate to one place of decimal, for example, the tilt can be 7.7 degree.
Uniquely identifies an adjacent node
Adjacent node identifier of this IP path
New name of the alarm
ANR mode
This parameter determines the noise depression degree. A large absolute value of this parameter corresponds to a
strong depression.
ANR target noise level
Whether to enable the adaptive noise restrain (ANR) function
Size of the azimuth angle of the cell antenna
Length of the feeder cable. The GPS satellite card is connected to the antenna through feeder cables. The
transmission delay on the feeder cable can be calculated on the basis of the length of the feeder cable, thus
Power supply switch of the GPS antenna feeder
E1T1 anti-error switch.
Whether to enable the BTS to clear the burglar alarm automatically
Number of the antenna
Number of the antenna feeder channel mapped to the RXU
Antenna pass No. of the RXU of a sub-location group. The parameter is configured only when the MRRU or GRRU is
used in the sub-location group.
Antenna pass number of the downlink tributary
Number of a port on the A interface board
Upper layer application type of the SCTP link. The upper layer application type of A and LB interface is M3UA. In the
BSC disaster tolerance, the application type is BBAP in the case of the communication between the primary and
Application type of the semi-permanent link
Update frequency of the value N (packet drop interval), indicating that the packet drop interval is updated after N
packets are transmitted.
Upper length threshold of the TBF buffer queue. If the length of the TBF buffer queue exceeds this threshold,
whether the packets are discarded is determined according to the packet discarding policy.
Congestion threshold of the TBF buffer queue. If the congestion level in the TBF buffer queue exceeds this
threshold, whether the packets are discarded actively is determined according to the packet discarding policy.
Initial value of the interval (indicated by N) at which the packets in the TBF buffer queue are discarded. The value N
indicates the frequency of discarding the packets in the TBF buffer queue. The greater the value N, the lower the
Lower threshold of the interval for discarding the packets in the TBF buffer queue, that is, the minimum value of N
(packet drop interval).
Upper threshold of the interval for discarding the packets in the TBF buffer queue, that is, the maximum value of N
(packet drop interval).
AQM switch
Target threshold of the TBF buffer queue
Local area code, for example, 021 for Shanghai
Area flag
Area flag
Threshold for reporting the recovery alarm for the abnormal release alarm. If the percentage of the abnormal channel
releases is equal to or less than this threshold, the recovery alarm for the abnormal release alarm is reported. That
Release statistics base for subchannels. This parameter indicates the number of times that a subchannel is
activated. In a timeslot, the release statistics base, B, multiplied by the number of channels, N, is the channel release
Threshold for reporting the abnormal release alarm. In a timeslot, the release statistics base, B, multiplied by the
number of channels, N, is the channel release sum, S. If the percentage of the abnormal channel releases in the
Retransmission times upon ARP timeout. When the ARP request times exceeds the retransmission time without a
response, the ARP/BFD detection failure alarm is reported. This may trigger the port or board switchover.
ARP packet timeout time
Number of the slot where the A interface board is located
Number of the slot where the A interface board is located
Number of the subrack where the A interface board is located
Network management type of the alarm. By default, all network management types are selected.
Network management type of the alarm. By default, all network management types are selected.
Switch for assigning the channel of a better cell to the MS during MS access.
When this parameter is set to ENABLE, if the cell supports direct retry and the current cell load is equal to or larger
than the value of "Cell direct retry forbidden threshold" in "SET GCELLOTHEXT" during the assignment, the
Offset relative to the level threshold for determining whether to assign a channel in the overlaid subcell
Number of the cabinet where the associated RXU board is installed. This parameter is valid for DRRU, MRRU,
GRRU, or BTS3900E board in the remote monitoring subrack of the DBS3036, DBS3900 GSM, or BTS3900E GSM.
Number of the cabinet where the associated RXU board is installed. This parameter is valid for DRRU, MRRU,
GRRU, or BTS3900E board in the remote monitoring subrack of the DBS3036, DBS3900 GSM, or BTS3900E GSM.
Number of the slot where the associated RXU board is installed.
Number of the slot where the associated RXU board is installed.
Number of the subrack where the associated RXU board is installed.
Number of the subrack where the associated RXU board is installed.
Absolute level threshold for automatic optimization of neighbor cells and frequencies. The measurement results in
measurement reports are screened and counted according to this threshold. If the signal strength of a neighbor cell
After the BSC6900 delivers an assignment command, the T3107 timer starts. If the BSC6900 receives an
assignment complete message within the scheduled time, the T3107 timer stops. If the timer expires, the BSC6900
Timer for waiting for a single A-interface circuit blocking or unblocking answer.
The BSC6900 starts this T1 timer after sending a single A-interface circuit blocking or unblocking message. If the
MSC reset protection timer, that is, interval between the time when the BSC6900 receives an MSC reset message
and the time when the BSC6900 answer to the MSC.
T17 timer. When receiving an MSC overload message or a single point congestion message for the first time, the
BSC6900 increases the level of the A interface flow control and starts the T17 and T18 timers at the same time.
T18 timer. When receiving an MSC overload message or a single point congestion message for the first time, the
BSC6900 increases the level of the A interface flow control and starts the T17 and T18 timers at the same time.
Timer for waiting for an A-interface circuit reset answer.
The BSC6900 starts this timer after sending an A-interface circuit reset message. When this timer expires for the first
Timer for waiting for an A-interface circuit group blocking or unblocking answer. After sending a CIC group
blocking/unblocking message over the A interface, the BSC6900 starts the timer T20. If the BSC6900 fails to receive
Timer for waiting for an A-interface reset answer
Whether to enable the ATCB handover algorithm for the concentric cell. According to the neighbor cell signal, the
ATCB handover algorithm determines the coverage of the overlaid subcell and balances the load between the
Hysteresis in the distance between the boundary of the overlaid subcell and the boundary of the underlaid subcell.
This parameter helps to adjust "Distance Between Boudaries of Subcells" and thus to prevent ping-pong handover
Distance between the boundary of the overlaid subcell and the boundary of the underlaid subcell. This parameter
specifies the difference between the coverage of the overlaid subcell and the coverage of the underlaid subcell in the
Whether to enable the BSC to use a 8 kbit/s timeslot to transmit 8 kbit/s data at the Ater interface
Whether to enable the BSC to assign half rate channels preferentially when the Ater interface is congested
Threshold for considering the Ater interface, if congested, the BSC determines whether to assign full or half rate
channels preferentially according to the congestion situations at the Ater interface. If the Ater resource usage
Index of an Ater connection path
Threshold for enabling the BSC local switching. When the congestion rate at the Ater interface exceeds this
threshold, the function is enabled.
Ater interface timeslot mask
Whether to configure the Ater OML link used for the TC subrack for the port. If it is actually configured and you
specify that it is not configured, the TC subrack fails to start. If it is not configured and you specify that it is already
Ater maintenance link index
Ater connection path index,The index is set through the ADD ATERCONPATH command.
Indentifies an Ater signaling channel
Transport mode of the Ater interface. The Ater interface can be in TDM or in IP transport mode.
Number of the RF port on the RF front-end board of the BTS. The number is unique in a board.
A interface timeslot mask
Attach-detach Allowed (ATT). If this parameter is set to YES, when an MS is powered off, the network does not
process any call connection for the MS as a called party. In this way, the network processing time and resources are
TMA attenuation factor of antenna tributary 1
TMA attenuation factor of antenna tributary 2
It specifies the loopback duration.
It specifies the test duration.
SSL authentication mode of the peer certificate
Validation mode of the PPP or MP link negotiation
Validation mode of the PPP or MP link negotiation
Validation mode of the PPP or MLPPP link negotiation
Username to validate, for the PPP or MP link negotiation
Username to validate, for the PPP or MP link negotiation
Username to validate, for the PPP or MLPPP link negotiation
Password to validate, upon PPP or MP link negotiation
Password to validate, upon PPP or MP link negotiation
Password to validate, upon PPP or MLPPP link negotiation
Type of validation protocol for the PPP or MP link negotiation
Type of validation protocol for the PPP or MP link negotiation
Type of the validation protocol for the PPP or MLPPP link negotiation
Whether the self-negotiation mode is adopted
1. When the FG2 board is used and the port type is GE, the self-negotiation mode must be adopted.
Whether inter-subrack path can be added automatically
Whether to allow automatic adjustment for the uplink threshold and hysteresis of full rate AMR call rates
Whether to allow automatic adjustment for the uplink threshold and hysteresis of half rate AMR call rates
Whether to enable the BSC to obtain BTS logs automatically
Whether to enable the auto-negotiation mode
The parameter specifies the work mode for the automatic download and activation of the BTS software. BTS
Software Auto DL and ACT indicates that the BTS boards are downloaded and activated as required. TMU Software
Auto unlock switch
Duration of time after which the locked user is unlocked automatically
optical adaptation type between high-order path and multiplex section.
Phase tag for GSM protocols supported by the A interface. The value of this parameter is chosen according to the A
interface phase tag provided by the MSC.
Alarm level for a digital port
Alarm level. It is valid for the digital port.
Threshold of B1 and B2 signal degrade. This parameter specifies the generation threshold and the recovery
threshold of the B1B2 signal degradation threshold in SDH frames at the optical port.
Threshold of B1 and B2 signal failure. This parameter specifies the generation threshold and the recovery threshold
of the B1B2 signal failure threshold in SDH frames at the optical port.
Threshold of B3 signal degrade. This parameter specifies the generation threshold and the recovery threshold of the
B3 signal degradation threshold in SDH frames at the optical port.
Threshold of B3 signal failure. This parameter specifies the generation threshold and the recovery threshold of the
B3 signal failure threshold in SDH frames at the optical port.
Switch of backplane LINE1
Switch of backplane LINE2
Directory for saving the backup file
Path (complete path) of the backup file
Quality threshold for determining that a call is disconnected because of poor quality. If the uplink quality or downlink
quality in the measurement reports during the period of "Timer for Bad Quality DISC Statistic" is higher than the
Whether the downlink TBF can be established in advance. Downlink TBF establishment in advance indicates that the
downlink TBF is established immediately after the MS establishes the uplink TBF rather than establishing the
Bar code 2 of the interface board of the BTS. This parameter is the electronic serial number of the standby PTU
board. An electronic serial number uniquely identifies an PTU board. This parameter is set before delivery.
IP address of the backup port
Mask of the backup port
This parameter specifies the method of saving the BTS backup power.
When this parameter is set to "Turn off TRX", the BSC preferentially shuts down some TRXs when the BTS
This parameter specifies the backup power saving policy of the BTS.
When this parameter is set to "Cover Priority", the BTS shuts down some TRXs, waits for a certain period of time,
Whether the cells at the 1900 frequency support high frequency 1900
Whether the cells at the 850 frequency support high frequency 1900
Whether the cells at the 900 frequency support high frequency 1900
Duration in which intra-cell handover is forbidden after the number of consecutive intra-cell handovers reaches the
maximum. Intra-cell handover can be conducted again only after this duration.
List of bar codes of all the cabinets in the BTS
The reference BTS must support the Um interface software synchronization.
Number of the temperature sensor corresponding to a battery group. You can choose sensor 1 (Battery1Temp) or
sensor 2 (Battery2Temp).
Number of the temperature sensor corresponding to a battery group.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Battery capacity.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether the configuration of external battery is allowed. The value "YES" indicates that the external battery can be
configured, and the value "NO" indicates that the external battery cannot be configured.
Allowed percentage of the battery discharging. After the AC power supply is cut and the power of the battery is
discharged by the value of this parameter, the diesel engine is started to supply the power.
Battery type.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Number of the BBAP service listening port
Reference difference between uplink and downlink levels. This parameter works with "Up Down Balance Floating
Range" to count uplink-downlink imbalances.
Battery capacity. The battery capacity should be set according to the vendor specification. If it is improperly
configured, the battery life may be shortened.
Base station color code (BCC) of a cell, provided by the network planning department. It is used for differentiating the
neighboring cells using the same BCCH frequency. A BCC and a network color code (NCC) compose a base station
Base station color code (BCC) of a cell, provided by the network planning department. It is used for differentiating the
neighboring cells using the same BCCH frequency. A BCC and a network color code (NCC) compose a base station
BTS color code. It uniquely identifies different BTSs that are adjacent and use the same TRX.
BCCH frequency of the cell
Frequency of the BCCH TRX
Frequency hopping mode of the TRX that carries the BCCH
Threshold for reporting the BC congestion alarm. When the BC congestion level exceeds the threshold, the BC
congestion alarm is reported.
Threshold for clearing the BC congestion alarm. When the BC congestion level is below the threshold, the BC
congestion alarm is cleared.
DSCP corresponding to the background service
Identifies one BC at the Gb interface board. The BCID's value range of PEUa board is 0~255 and that of POUc
board is 0~511.
Current limit coefficient of the battery. The maximum charging current equals the value of "Battery Current Limiting
Coefficient" multiplexed by "Battery Capacity". If the charging current is 5 A higher than the maximum charging
Boost-Charging Voltage. See the vendor specification for the setting of this parameter.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether the configuration of external battery is allowed.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
ARP1 priority in the BE service. ARP1 priority weight determines the number of the budget blocks and the block
scheduling priority.
ARP2 priority in the BE service. ARP2 priority weight determines the number of the budget blocks and the block
scheduling priority.
ARP3 priority in the BE service. ARP3 priority weight determines the number of the budget blocks and the block
scheduling priority.
DSP bearer type.
MTP3: indicates that the lower layer bearer is the MTP3 used in ATM/TDM scenario;
Time interval for sending a handshake message between BSC6900s. The parameter checks whether the
communication among BSCs in a redundancy group is normal.
Average period for sending the measurement report over the EGPRS channel
Number of UTRAN TDD cells that should be included in measurement report
This parameter specifies whether to allow 3G better cell handover algorithm.
Whether to enable the algorithm for the handover to a better cell
According to the P/N rule, if the conditions for the handover to a better cell due to interference are met for P seconds
within N seconds, the handover is triggered.
According to the P/N rule, if the conditions for the handover to a better cell due to interference are met for P seconds
within N seconds, the handover is triggered.
Timeout times of the BFD packet. If several consecutive BFD packets are not received, the BFD session is set to the
DOWN state.
BFD Session No.
Allowed fluctuation of the difference between uplink and downlink levels relative to the reference difference. If the
difference between uplink and downlink levels is outside the fluctuation range, the uplink and downlink are
Mutual-aid changeback policy of baseband frequency hopping (FH). If multiple TRXs in a baseband FH group are
faulty and changeback is needed after mutual aid of the baseband FH TRXs occurs: If you choose ALL, mutual-aid
Bit offset in the frame of the BTS clock
ARP1 priority in the Background service. ARP1 priority weight determines the number of the budget blocks and the
block scheduling priority.
ARP2 priority in the Background service. ARP2 priority weight determines the number of the budget blocks and the
block scheduling priority.
ARP3 priority in the Background service. ARP3 priority weight determines the number of the budget blocks and the
block scheduling priority.
Base Station Controller alarm blink filter switch
Alarm blink filter threshold. When the interval between the generation and clearance of an alarm is equal to or
smaller than the alarm blink filter threshold, the alarm is filtered and not reported to the NMS.
Measurement period of filtered Base Station Controller alarms
Switch controlling whether to perform statistics of Base Station Controller alarms
Retry times after the peer response timer expires during NSVC blocking
Duration of the peer response timer during NSVC blocking
Number of the port in the BM subrack where one end of the ATER connection channel is located
Number of the slot in the BM subrack where one end of the ATER connection channel is located
Number of the BM subrack where one end of the ATER connection channel is located
Duration of the flow control protection timer enabled during the flow control between the TCS and the MPS/EPS
subracks
Whether to use the device IP address as the local IP address. When this parameter is set to "YES", the device IP
address is used as the local IP address of the PPP link. When this parameter is set to "NO", the device IP address is
Whether to report the alarm to the alarm box
Position of break point 1 in an RXU chain. The number of break points must not be greater than the number of RXU
boards in the RXU chain.
Position of break point 2 in an RXU chain. The number of break points must not be greater than the number of RXU
boards in the RXU chain.
Whether to enable the bad quality (BQ) handover algorithm. Whether to trigger BQ handover depends on the uplink
and downlink transmit quality (measured by using BER). If the uplink or downlink BQ exceeds the BQ handover
According to the P/N rule, if the conditions for emergency BQ handover are met in P of N measurement reports, the
handover is triggered.
If ("downlink level of the neighbor cell after filtering" - "downlink level of the serving cell (after power control
compensation)") > ("Inter-cell HO Hysteresis" - "BQ HO Margin" + 64), the BQ handover to the neighbor cell is
According to the P/N rule, if the conditions for emergency BQ handover are met in P of N measurement reports, the
handover is triggered.
Classes of boards classified according to function modules
Classes of boards classified according to function modules
Classes of boards classified according to function modules
Classes of boards classified according to function modules
Number of the board
Number of the RF front-end board in the BTS
The upper threshold of the total receive bandwidth of all the TRXs bound to the board, for example, when this value
is 250, it means the the total receive bandwidth should be no more than 25Mbits/s.
Software type of the BTS board
The upper threshold of the total send bandwidth of all the TRXs bound to send pass of board, for example, when this
value is 150, it means the the total send bandwidth should be no more than 15Mbits/s.
Type of the board
Type of the board
Board type
Board type
Board type
Board type
Type of the new RXU board.
Type of the board. The type can be TMU/DTMU, DTRU, DPTU, QTRU, MRRU, GRRU, BTS3900B, MRFU, GRFU,
BTS3900E, DRFU, DRRU, UBRI or UTRP.
To avoid intermittent blinking, the switchover cannot be performed over a certain period of time when the OML is
disconnected. That period of time is specified as ring II wait time before switch.
Contents of a cell broadcast message
Time interval for a cell broadcast message
Backup mode of the log. If "ENTIRE" is selected, all logs in the current database are backed up. If "INCREMENTAL"
is selected, the logs generated after last backup are backed up.
BS-AG-BLKS-RES, indicating the number of the CCCH message blocks reserved for the AGCH. After the CCCHs
are configured, the value of this parameter indicates the actual seizure rates of the AGCHs and the PCHs over the
DPC of the external BSC, which is used for inter-BSC communication. This parameter can be represented in
decimal, hexadecimal, and binary. By default, this parameter is represented in decimal. To represent this parameter
This parameter specifies whether to enable the TRX Intelligent Shutdown feature.
It indicates whether the A interface E1/T1 is the primary BSC6900 or secondary BSC6900.
Gateway IP address of the BSC6900. When the BSC provides the function of simple cell broadcast, the BSC6900
sends cell broadcast messages through this IP address defined by this parameter.
End time for collecting the inter-BSC offset information
Start time for collecting the inter-BSC offset information
Uniquely identifies a BSC in the TC pool
ID of the BSC that controls the external 2G neighbor cell
Period for fine tuning the BTS clock between BSCs
IP address of the BSC6900. If the connection mode of the BSC6900 and the CBC is to lead cables out of the PIU,
the value of this parameter must be the same as the preset IP address of the PIU port.
IP address of an interface board on the BSC6900 side
Conditions for enabling the function of BSC local switching.
UNCONDITIONALSTART: The function of BSC local switching is enabled without restriction.
Unique name of the external BSC
Whether to allow high-priority calls to preempt the radio resources of low-priority calls when radio resources are
insufficient.
Whether to allow the call during an intra-BSC emergency handover to preempt the radio resources of low-priority
calls in the target cell.
In-BSC6900 port No. of the monitoring timeslot
Port number used for the communication between the BSC6900 and the CBC
Whether to allow the eMLPP priorities to be classified into two types: high priority and normal priority.
If this parameter is set to YES, then during the resource preemption, the priorities of all the services are compared,
Whether to allow calls to queue for radio resources when radio resources are insufficient.
Whether to allow the service during an intra-BSC emergency handover to queue for radio resources in the target cell.
Reserved parameter 1 that is effective at the BSC level
Reserved parameter 10 that is effective at the BSC level
Reserved parameter 11 that is effective at the BSC level
Reserved parameter 12 that is effective at the BSC level
Reserved parameter 13 that is effective at the BSC level
Reserved parameter 14 that is effective at the BSC level
Reserved parameter 15 that is effective at the BSC level
Reserved parameter 16 that is effective at the BSC level
Reserved parameter 17 that is effective at the BSC level
Reserved parameter 18 that is effective at the BSC level
Reserved parameter 19 that is effective at the BSC level
Reserved parameter 2 that is effective at the BSC level
Reserved parameter 20 that is effective at the BSC level
Reserved parameter 21 that is effective at the BSC level
Reserved parameter 22 that is effective at the BSC level
Reserved parameter 23 that is effective at the BSC level
Reserved parameter 24 that is effective at the BSC level
Reserved parameter 25 that is effective at the BSC level
Reserved parameter 26 that is effective at the BSC level
Reserved parameter 27 that is effective at the BSC level
Reserved parameter 28 that is effective at the BSC level
Reserved parameter 29 that is effective at the BSC level
Reserved parameter 3 that is effective at the BSC level
Reserved parameter 4 that is effective at the BSC level
Reserved parameter 5 that is effective at the BSC level
Reserved parameter 6 that is effective at the BSC level
Reserved parameter 7 that is effective at the BSC level
Reserved parameter 8 that is effective at the BSC level
Reserved parameter 9 that is effective at the BSC level
In-BSC6900 slot No. of the monitoring timeslot
In-BSC6900 subrack No. of the monitoring timeslot
In-BSC6900 sub-timeslot No. of the monitoring timeslot. If the added monitoring timeslot works at 64 kbit/s, the sub-
timeslots are numbered from 0. If the added monitoring timeslot works at 32 kbit/s, the sub-timeslots are numbered
When the BTS clock is adjusted, the offset is added to obtain better network performance.
ID of the BSC at the other end of the link. In non-TC pool scenario, this parameter specifies the ID of the primary
BSC. In TC pool scenario, this parameter specifies the ID of the BSC that is at the other end of the link.
ID of slave BSC in TC Pool
In-BSC6900 timeslot No. of the monitoring timeslot
This parameter is used to set the parameter BS_CV_MAX for MS countdown. This parameter is used for the MS to
calculate the CV. This parameter also determines the duration of the timer T3198. When the MS sends one uplink
Whether to enable the BTS to transfer BTS/MS power class to the BSC
Number of PAGCH blocks
Number of multiframes in a cycle on a paging sub-channel. In fact, this parameter specifies the number of paging
sub-channels that a paging channel in a cell is divided into.
Number of PBCCH blocks
Number of PRACH blocks
General strategy of the BSS local switching, which includes the BSC local switching and the BTS local switching. The
two functions cannot be enabled at the same time.
Type of the BSS local switching with the cooperation of the MSC.
NONSUPPORT: When performing local switching, the BSS need not determine whether the MSC allows an MS to
Whether to support the paging function of the CS domain of the A interface. Yes: the MS can be called upon paging
request on the A interface when handling the PS service; No: the MS cannot be called upon paging request on the A
Type of the board
Type of the board
Type of the board
Board type
Board type
Board type
Board type
Board type
Board type
Board type
Type of the board that controls the RET antenna.
1. DATU: It may represent the DATU or the DATM and is applicable to the BTS3012, BTS3012AE, BTS3012_II,
Type of the newly added antenna board
Type of the newly added board
Type of the newly added RXU board
Type of the board
Type of the board
The configuration flag specifies the operation is on the BM or TC.
Identifies the BM subrack or TC subrack of the BSC.
When this parameter is set to "CFGBM", a BM signaling link is added.
This parameter specifies whether to enable the TRX Working Voltage Adjustment feature. When this parameter is
set to YES, the BSC6900 supports the feature where the power amplifier can use different working voltages in
Bard code of BTS BBU board.
Communication type of a BTS
Communication type of a BTS
Peer equipment type of the BTS. This parameter indicates whether to connect the BTS to the BSC6900 or cascade
the BTS to another BTS.
BTS detection switch. If the parameter is set to "CLOSE", the function of detecting the BTS is disabled. If the
parameter is set to "OPEN", the function of detecting the BTS is enabled. When the function of detecting the BTS is
BTS index of the adjacent node to be added. The parameter is valid only when Adjacent node type is set to Abis.
Index of the BTS, uniquely identifying a BTS in a BSC6900.
Index of the BTS running the command
Number of the BTS connected to the BSC. The number is unique in a BSC
List of BTS indexes. You can specify multiple BTSs,separated by "&" and "&&". For example, "1&2&3&4&5" or
"1&&5".
Whether to collect offset information by BTS index or BTS name
Index type of the BTS. BYNAME: query by BTS name; BYID: query by BTS index.
Base station index, 65535 indicate all base stations.
IP address of a BTS. When "BTS Com Type" is set to "LOGICIP", the value of the parameter is the IP address of the
BTS. When "BTS Com Type" is set to "PORTIP", the value of the parameter is the IP address of the BTS ethernet
Conditions for enabling the function of BTS local switching.
UNCONDITIONALSTART: The function of BTS local switching is enabled without restriction.
Subnet mask of BTS.
Whether to enable the BTS to preprocess measurement reports. This parameter determines where to conduct power
control.
Name of the BTS, uniquely identifying a BTS in a BSC6900. This parameter cannot contain , ; = " ' more than two
(include two) %, more than two (include two) space, more than three (include three) +.
Connect BSC BTS Name.It is unique in one BSC.This parameter cannot contain ? | : < > " @ # ! % ^ & * . [ ] / \ \\ '.
List of BTS names. You can specify multiple BTSs, separated by "&". For example, "Name1&Name2".
If the parameter is set to "ON", all the Ping packets are sent.
If the parameter is set to "OFF", all the Ping packets are discarded.
This parameter specifies whether the BSC is allowed to shut down the BCCH TRX that is configured as "Shut Down
Enabled" to save power after the BSC receives a power failure message from the BTS.
Maximum degree by which the BSC can control the power of the BTS dynamically
Whether to specify "Power Control threshold Adjust for SAIC" in the MML command "SET GCELLPWR3"
Software version number of the BTS
Transmission compression ratio of a BTS. 1. Modifying the settings of "Transfers Compress Rate" may change the
bandwidth required by the BTS. That is, the current bandwidth may be excessive or insufficient. If the bandwidth is
Type of the BTS
Type of the BTS
Type of the BTS
Time for which the BTS waits to restore a BFD session
Type of TRX loopback test
Battery type.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
If the OML is not established at one port after a period of time, the OML switches to another port and tries to connect
to this port. That period of time is called ring II rotating duration time.
Whether to enable the data binding function
Identifies a unique PTP BVC with NSE
The BSSGP virtual connection identifier. It is used to identify multiple BVCs that multiplexes the NS-VC.
Duration of BVC flow control timer F. A cell sends the flow control message at the interval specified by this timer.
Switch for adjusting the dynamical bandwidth of the logical port. If this switch is turned on, the system adjusts the
dynamical bandwidth of the logical port according to the transmission quality of the link monitored by the IPPM. After
If the available backward bandwidth is less than or equal to this value, the backward congestion alarm is emitted and
backward congestion control is striggered.
If the available backward bandwidth is greater than this value, the backward congestion alarm is cleared and
backward congestion control is stopped.
If the ratio of available backward bandwidth is greater than this value, the backward congestion alarm is cleared and
backward congestion control is stopped.
If the ratio of available backward bandwidth is less than or equal to this value, the backward congestion alarm is
emitted and backward congestion control is triggered.
If the available backward bandwidth is greater than this value, the backward overload congestion alarm is cleared
and backward overload control is stopped.
If the ratio of available backward bandwidth is greater than this value, the backward overload congestion alarm is
cleared and backward overload control is stopped.
If the available backward bandwidth is less than or equal to this value, the backward overload congestion alarm is
emitted and backward overload control is triggerd.
If the ratio of available backward bandwidth is less than or equal to this value, the backward overload congestion
alarm is emitted and backward overload control is triggered.
Ratio of reserved backward bandwidth for handover user
Reserved backward bandwidth for handover user
Maximum ratio of the estimated bottleneck bandwidth
Bandwidth mode
Threshold of bandwidth change based on the load control algorithm. When the system detects that the change of the
available bandwidth exceeds this threshold through the IPPM, the system starts adjusting the bandwidth of the
Threshold for reporting the uplink-downlink imbalance alarm. If the percentage of the uplink-downlink imbalance
measurement reports in the total valid measurement reports is equal to or greater than this threshold, the uplink-
Index type. The value can be BYIDX or BYNAME.
Whether the reselection hysteresis parameter is applied to the C31 criterion
Whether GPRS cell reselection offset is used for C32 calculation during cell reselection. If this parameter is set to 1,
then only the positive hysteresis of the neighoring cell is used in C32 calculation.
Descriptive information of the BTS cabinet
List of all the cabinet numbers in the BTS
Whether the added cabinet is a remote cabinet
Whether to allow call re-establishment. Burst interference or blind spots due to high buildings may lead to a radio link
failure. If a call drop is caused by such a failure, the MS can start call re-establishment to resume the conversation.
Calibration value of the clock
Whether an MS uses the calculated value as the final receive level value. The calculated receive level value is the
measured receive level value minus the receive level value obtained from the BCCH TRX timeslots. This parameter
Whether to enable the capacity and coverage of the BTS to be automatically optimized according to the actual
situation of the incumbent network.
Card Frequency Attribute
Whether to indicate that the IP Path is carried on the IP logic port or resource group. NULL indicate the IP Path is
carried on the physics port.
Bearer type of the logical port
Port type of the SBFD/ARP bearer
Used together with "Cell Bar Qualify" to decide the priority status of a cell. Refer to GSM Rec. 04.08.
Cell Bar Qualify Cell Bar Access Cell selection priority Cell reselection priority
Uniquely identifying a cell broadcast center (CBC)
IP address of a CBC
CBC interface parameter. The value of this parameter must be translated into a binary numeral. The following
describe each bit of the value:
Port number at the CBC side in the communication with the BSC6900
Duration of no cell broadcast message at the Cb interface. If the BSC6900 does not receive any message from the
CBC during the preset value of this parameter, the BSC6900 considers that the connection with the CBC has been
Used together with "Cell Bar Access" to decide the priority status of a cell. See GSM Rec. 0408. This parameter does
not affect cell reselection but cell selection only.
Maximum burst size (MBS)
Timer interval for sending handshake messages. According to the value of this parameter, the BSC6900 regularly
sends the CBC a handshake message to decide whether the communication between the BSC6900 and the CBC is
Number of enhanced measurement reports (EMRs) sampled for averaging the CV_BEP on the SDCCH. Averaging
the CV_BEP in multiple EMRs helps to prevent the incomprehensiveness of a single EMR.
Number of enhanced measurement reports (EMRs) sampled for averaging the CV_BEP on the TCH. Averaging the
CV_BEP in multiple EMRs helps to prevent the incomprehensiveness of a single EMR.
Country code, for example, 86 for China
Whether to enable the certificate chain
DISABLE: indicating that the certificate chain is disabled
Time interval for sending overload messages, used for the BTS to notify the BSC6900 of the load over a specific
CCCH timeslot. See GSM Rec. 0508.
This parameter is used by the BTS to inform the BSC of the load on a CCCH timeslot, that is, the load of the access
requests on the RACH and the load of all the messages (such as paging messages and packet immediate
DSCP corresponding to the session service
Transmission period of the CCM packet in the MA
Threshold of forbidding directed retry for cells. When the value of "Assignment Cell Load Judge Enable" in "SET
GCELLCCBASIC" is ENABLE, if cells support directed retry and the current cell load is greater than or equal to the
Offset of the measurement report of the cells at the 1800 MHz frequency. Before cells are sequenced by priority,
according to frequencies, the value of this parameter must be added to the receive level value in the measurement
Threshold of the measurement report of the cells at the 1800 MHz frequency. When the receive level value in the
measurement report of the cells at the 1800 MHz frequency exceeds the value of this parameter, the report takes
BCCH frequency of a 2G neighbor cell that MSs can measure in idle mode. Recording the BCCH frequencies of 2G
neighbor cells that MSs can measure in idle mode, the BA1 table is sent in System Information 2, 2bis, and 2ter.
Whether to generate the 2G BA1 table automatically according to neighbor cell relations or to input the 2G BA1 table
manually. Recording the BCCH frequencies of 2G neighbor cells that MSs can measure in idle mode, the BA1 table
BCCH frequency of a 2G neighbor cell that MSs can measure in dedicated mode. Recording the BCCH frequencies
of 2G neighbor cells that MSs can measure in dedicated mode, the BA2 table is sent in System Information 5, 5bis,
This parameter indicate whether to generate the 2G BA2 table automatically according to neighbor cell relations or to
input the 2G BA2 table manually. Recording the BCCH frequencies of 2G neighbor cells that MSs can measure in
Timeslot power attenuation level of the EDGE TRX in 8PSK. The attenuation level ranges from 0 to 50, each of
which corresponds to an attenuation of 0.2 dB.
Offset applied to the receive level of a GSM900 cell in the measurement report before prioritizing cells by frequency
bands. Before cells are sequenced by priority, according to frequencies, the value of this parameter must be added
Threshold of the measurement report of the cells at the 900 MHz frequency. The measurement report is valid only
when the receive level in the measurement report of the GSM900 cell exceeds this threshold. After being filtered, the
Whether the cell can be added to the reselected candidate cell list. If this parameter is set to "NoPermit", the cell
cannot be reselected as the candidate cell for handover. If this parameter is set to "Permit", the cell can be
If the coverage type of a cell is outdoor coverage, the BTS detects whether the standing wave alarm is generated
only when the forward power is greater than 35 dBm.
Even charging voltage of the battery. The battery is charged at the voltage as specified by this parameter.
Even charging voltage of the battery. The battery is charged at the voltage as specified by this parameter.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Float charging voltage of the battery. The battery is charged at the voltage as specified by this parameter.
Float charging voltage of the battery. The battery is charged at the voltage as specified by this parameter.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Index of a cell, uniquely identifying a cell in a BSC6900
ID of the cell. The cell ID cannot conflict with other cell IDs in the BSC.
Index of a cell, uniquely identifying a cell in a BSC
Index of a cell, uniquely identifying a cell in a BSC6900
Index of a cell, uniquely identifying a cell in a BSC6900
Cell Index
List of the user-defined neighbor cells to be measured. This parameter is represented as a character string where the
IDs of the cells to be measured are separated by &, such as 1&2&5.
Index type of a cell when this command is executed
Index type of the cell
Index type of the cell. BYNAME: query by cell name; BYID: query by cell index.
This parameter specifies whether a cell is the OL subcell or the UL subcell. This parameter is applied to the
enhanced dualband cell.
Layer of the cell. If the layer of the cell is lower, it is more likely that a handover to the cell will be triggered.
List of cell indexes. All cell indexes are combined as a character string, separated by "&". For example, 1&2&5.
Whether an assignment complete message contains a cell list.
According to GSM Rec. 08.08, during a channel assignment, an assignment complete message contains a cell list
Maximum number of SDCCHs in the cell. Before converting a TCH into an SDCCH, the BSC compares the number
of SDCCHs after the conversion in the cell with "Cell SDCCH Channel Maximum". If the number of SDCCHs after
Name of a cell, uniquely identifying a cell in a BSC6900
Name of a cell, uniquely identifying a cell in a BSC
Name of a cell, uniquely identifying a cell in a BSC6900
List of cell names. All cell names are combined as a character string, separated by "&". For example,
cell1&cell2&cell5. The cell name should not contain the following characters:
Power of each passage on the MRRU in the cell. When multiple operators are configured on an MRRU, the
parameter specifies the power of each operator on the MRRU.
Threshold of the downlink receive level of an over-coverage cell. If the downlink level of a cell is higher than the
value of this parameter and the timing advance (TA) is greater than the value of "Cell Over Coverage TA Threshold"
Threshold of the TA of an over-coverage cell. If the downlink level of a cell is higher than the value of this parameter
and the timing advance (TA) is greater than the value of "Cell Over Coverage TA Threshold" in more than 20%
Maximum number of reported paging overload messages in the cell. If the BSC allows the flow control on the re-
paging messages, and the number of the reported paging overload messages exceeds the value of this parameter,
Whether to allow the power-off of the battery.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Battery power-off voltage.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
This parameter specifies whether a 2G cell or 3G cell is selected in the inter-RAT cell reselection procedure.
The number of times that the downlink transmission quality of the MS is lower than the transmission quality threshold
of the MS ("EDGE GMSK Quality Threshold", "EDGE 8PSK Quality Threshold", or "GPRS Quality Threshold" by
Information about the cell scenario. It needs to be sent to the BTS. Based on the information, the BTS optimizes the
allocation of resources.
This parameter specifies whether to allow a mobile phone to preferentially camp on a 3G cell after a call is
terminated in the areas covered by both the GSM network and the UMTS network.
The BTS reports an alarm if the temperature of battery group 1 exceeds the value of this parameter.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
The BTS reports an alarm if the temperature of battery group 1 is lower than the value of this parameter.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Upper limit of the temperature measured by the temperature sensor of the battery group 1. If the measured value is
greater than the value of this parameter, the value of this parameter is reported.
Lower limit of the temperature measured by the temperature sensor of the battery group 1. If the measured value is
smaller than the value of this parameter, the value of this parameter is reported.
Whether to allow the configuration of parameters related to the temperature compensation of the battery group
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Threshold of the downlink receive level of an weak-coverage cell. If the downlink level of a cell is lower than the
value of this parameter and the timing advance (TA) is smaller than the value of "Cell Weak Coverage TA Threshold"
Threshold of the TA of an weak-coverage cell. If the downlink level of a cell is lower than the value of this parameter
and the timing advance (TA) is smaller than the value of "Cell Weak Coverage TA Threshold" in more than 30%
Threshold for stopping LAPD link congestion control. This parameter cannot be set too small. If this parameter is set
too small, the congestion control duration is too long, and thus the transmission capability of signaling links cannot be
Name of the certificate chain file
Whether to allow the configuration of alarm parameters. The value "YES" indicates that the configuration is allowed,
and the value "NO" indicates that the configuration is not allowed. If the parameter is set to "YES", all the other
Indicates whether the IP path is carried on the IP logic port or the resource group.
BTS configuration modes include auto plan mode and normal mode.
In auto plan mode, the user can enable the auto planning algorithms and auto optimization algorithms according to
Configure switch.
Whether to enable the board parameters to be configured. If this parameter is set to "YES", the user can set board
parameters of the BTS cabinet. Otherwise, the user cannot set the board parameters.
Whether to enable the board parameters to be configured. If this parameter is set to "YES", the user can set the
cabinet power type. Otherwise, the user cannot set the cabinet power type.
Confirm password. The confirm password is required to ensure that a correct password is entered.
Customized command group to be processed
This parameter is valid only when the operator belongs to the custom level.
Congestion end threshold. If the congestion end threshold is large, the congestion control ends earlier. As a result,
the congestion control effect is poor. The work of the Ater signaling link is deteriorated.
Congestion end threshold. If the congestion end threshold is large, the congestion control ends earlier. As a result,
the congestion control effect is poor. The work status of the Ater signaling link is deteriorated.
If the parameter is set to 1, it indicates that the CGI and RAC data is generated through automatic planning. If the
parameter is set to 0, it indicates that the data needs to be manually entered.
Name of the command group. You can define the name.
Number of the cabinet group where the idle timeslot is located.
Congestion start threshold. If congestion start threshold is set to a large value, there will be a time lag in the
congestion control and the work of the signaling link gets deteriorated. The interval between congestion start
Congestion start threshold. If congestion start threshold is set to a large value, there will be a time lag in the
congestion control and the work of the signaling link gets deteriorated. The interval between congestion start
Congestion start threshold. If congestion start threshold is set to a large value, there will be a time lag in the
congestion control and, the work of the signaling link gets deteriorated. The interval between congestion start
This parameter indicates the geographical relationship between the neighboring cell and the serving cell. In the
BSC6900, if direction A is selected, then the reverse direction is B.
Combination type of chains. "CHAINTORING" indicates that one chain changes to a ring, and "COMBINECHAINS"
indicates that two chains are combined into one ring.
Channel assignment priority of the cell
If this parameter is set to CAPABILITY, the factors are listed as follows in a descending order of priority: capacity
This parameter specifies the proportion of available PDCHs in a cell. When the proportion of available PDCHs in the
cell is lower than this threshold, the BSC generates an alarm. When the proportion of available PDCHs in the cell is
This parameter determines whether to activate the function of monitoring the failure of logical channels in a cell.
When this function is activated and the proportion of faulty logical channels in the cell exceeds a predefined
This parameter specifies the proportion of available TCHs in a cell. When the proportion of available TCHs in the cell
is lower than this threshold, the BSC generates an alarm. When the proportion of available TCHs in the cell is higher
Channel number of a simple cell broadcast message. This is a key parameter for adding a simple cell broadcast
message. You can use "DSP GSMSCB" to query and obtain the value of this parameter.
Whether to measure the channel interference during channel assignment. If this parameter is set to NO, the BSC
does not measure the channel interference or send an interference indication during channel assignment. If this
When the value of this parameter is YES, if the assignment request message sent by the MSC contains the channel
rate type indicating the support of both full and half rates, and contains the speech version indicating the selection of
This parameter is used to check whether the Abis timeslot for the PDCH is faulty. When the out-of-synchronization
period of the PDCH primary link exceeds the value of this parameter, the Abis timeslot for the PDCH is regarded as
Number of ping check timeouts. The parameter indicates the number of timeout record failures.
Whether to enable the BSC to check automatically whether a BTS is connected to a proper E1 port in the EIUa. If a
BTS is connected to an E1 port configured for another BTS in the EIUa, the BTS cannot be reset automatically after
Alarm mode of the ANT_A tributary of an RXU board. There are three alarm modes. Alarm mode 1 has only one type
of alarms. The alarm current is fixed and greater than the normal working current.
Alarm mode of the ANT_B tributary of an RXU board. There are three alarm modes. Alarm mode 1 has only one type
of alarms. The alarm current is fixed and greater than the normal working current.
Detection index. The index is a unique value ranging from 0 to 511 if it is not specified.
Detection index
Total number of times that the BTS checks whether to switch off the air conditioner
Total number of times that the BTS checks whether to switch on the air conditioner
Whether to perform checksum when receiving message
Whether to perform checksum when sending message
Checksum arithmetic type. According to the RFC4960, the ALDER32 algorithm is not applicable to the SCTP
checksum. The CRC32 is recommended.
Type of the detection that is performed between the BSC and the gateway.
Duration
Number of the channel in the TRX
Timeslot for playing sound
Number of the channel in the TRX
Type of channel loopback test
Channel type of the timeslot on the TRX. The channel type of timeslot 0 must not be set, because the combined
BCCH is configured by default. The channel type of other timeslots can be set to full-rate TCH or half-rate TCH.
Whether an assignment complete message contains the information element of Chosen Channel
Whether a handover perform message contains the information element of Chosen Channel
Whether an HO REQ ACK message contains the information element of Chosen Channel
Whether an encryption complete message contains the information element of Chosen Encryption Algorithm
Whether a handover performed message contains the information element of Chosen Encryption Algorithm
Whether an assignment complete message contains the information element of Chosen Encryption Algorithm
Whether an HO REQ ACK message contains the information element of Chosen Encryption Algorithm
Whether to allow a multi-density TRX board, that uses the dynamic power sharing algorithm to assign channels, to
assign a channel to an MS when the remaining power on the multi-density TRX board is less than the power required
This parameter indicates whether to collect CHR logs for a specified object.
Maximum number of allowable CS domain channel request messages within the value of "CHAN REQ Statistical
Period"
Average number of allowable PS domain channel request messages within the value of "CHAN REQ Statistical
Period"
Statistic period of the arrival rate of channel request messages. Within the preset value of this parameter, the
BSC6900 counts the number of channel request messages. Once the current total number of times exceeds the
Type and function of the channel
Identity code of a cell, A cell is a wireless coverage area identified by a base station identity code and a global cell
identification.
Cell identity code. The cell is a radio coverage area that is identified by the BTS identity code and global cell identity
code.
Indicates the A interface CIC. When operation mode is set to OPC index, DPC group index, BSC ID, or CIC, the
parameter is mandatory. The parameter supports multiple values.
Indicates the Pb interface CIC. If the search object mode is set to search by the specified No., the parameter is
mandatory.
The TC DSP compares neighboring speech frame samples after the CIC downlink one-way mute detection is
enabled. When the number of times with different results exceeds the value of this parameter, it is regarded that no
This parameter indicates the period of completing a CIC downlink one-way mute detection of each port.
This parameter determines whether the CIC downlink one-way mute detection is enabled.
This parameter indicates the proportion of one-way mute CICs in all available CICs over a port.
If one-way mute frames occur for the duration greater than "CIC Downlink One-Way Mute Detection Duration", then it
is regarded that a one-way mute event occurs for the current call.
Whether an assignment failure message contains the information element of Circuit Pool
Whether an HO FAIL message contains the the information element of Circuit Pool
Whether an assignment failure message contains the the information element of Circuit Pool List
Whether an HO FAIL message contains the the information element of Circuit Pool List
Whether an assignment complete message contains the information element of Circuit Pool
Whether an HO REQ ACK message contains the information element of Circuit Pool
Bandwidth of the logical port
This parameter specifies the estimated carrier-to-interference ratio of a new call. It is used for the Huawei power
control algorithm III to calculate the power of the call.
Slot number of the BSC6900 board that is connecteds to the BTS
Subrack number of the BSC6900 board that is connected to the DXX
Whether the cell supports the MS with the DTM multi-timeslot capability of class 11
Whether to enable the BSC to include the 3G classmark information element in the Classmark Request message
that the BSC forwards from the MSC to an MS
Error clear threshold.
Clock mode
Type of the clock protocol for the IP clock server
Type of the clock board
Clock mode of the BTS.
If this parameter is set to INT_CLK, the BTS does not track any external clock. The internal high precision clock
Delay for which the BTS waits to run the burglar alarm clearance command after reporting the burglar alarm
Whether the alarm to be queried is cleared. You can select "cleared" or "uncleared", or both of them. By default, both
of them are selected.
Interval at which the BTS runs the burglar alarm clearance command automatically
Name of the command to be queried. You can select one or more commands.
You can select one or more commands.
Sequence number of the command string of the scheduled subtask.
Number of the cabinet
Number of the cabinet
Number of the cabinet
Number of the cabinet where the port is located
Number of the cabinet
Number of the cabinet.
Time delay in the detection of core network interface failure. Within the preset value of this parameter, the BSC6900
continuously detects core network interface failures and then releases the management right of service objects.
Used to uniquely identify an MSC
Uniquely identifies a node of SGSN, with the specified operator name
Index of an MSC. It is used in storing and querying the MSC attributes
Index of the operator
Policy of the BSC6900 for judging whether the interface status of the core network is normal. If the value is NONE,
the BSC6900 does not change the service management right. If the value is AINTFBLOCK, the BSC6900 releases
Number of returned alarm records. By default, all records can be returned in each query.
Type of the cabinet. The slot and subrack arrangements in a cabinet vary according to the cabinet type.
Type of the BTS cabinet where the DMPU is installed
Maximum number of records allowed in the operation log
Assume that this threshold is not 0. When the accumulated number of alarm blink times exceeds the threshold, the
alarm is reported. For querying the alarm blink measurement period, see "LST ALMBLKSW". For setting the alarm
Assume that this threshold is not 0. When the number of alarm blink times is smaller than the threshold, the alarm is
reported. For querying the alarm blink measurement period, see "LST ALMBLKSW". For setting the alarm blink
Whether to adjust the candidate cell queue to give priority to intra-BSC/MSC handover
Number of a simple cell broadcast message. You can run "DSP GSMSCB" to query and obtain the information.
The value of this parameter cannot be 0.
Whether to start the refrigeration equipment of the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether to collect offset information by the BTS or cell
Combined loss used to estimate the downlink power during assignment
Level of common access control, used for load control, allowing or forbidding the access of some users of common
access levels
Complexity of the password
BTS compress rate.
Whether the BSC that controls the external cell and the local BSC belong to the same MSC
Index type of the BTS connected to BSC
If the duration for buffering the data in queue 0 is less than or equals to the value of this parameter, flow control is
canceled.
If the duration for buffering the data in queue 1 is less than or equals to the value of this parameter, flow control is
canceled.
If the duration for buffering the data in queue 2 is less than or equals to the value of this parameter, flow control is
canceled.
If the duration for buffering the data in queue 3 is less than or equals to the value of this parameter, flow control is
canceled.
If the duration for buffering the data in queue 4 is less than or equals to the value of this parameter, flow control is
canceled.
If the duration for buffering the data in queue 5 is less than or equals to the value of this parameter, flow control is
canceled.
If the duration for buffering the data in queue 0 is more than or equals to the value of this parameter, flow control is
triggered.
If the duration for buffering the data in queue 1 is more than or equals to the value of this parameter, flow control is
triggered.
If the duration for buffering the data in queue 2 is more than or equals to the value of this parameter, flow control is
triggered.
If the duration for buffering the data in queue 3 is more than or equals to or equals to the value of this parameter,
flow control is triggered.
If the duration for buffering the data in queue 4 is more than or equals to the value of this parameter, flow control is
triggered.
If the duration for buffering the data in queue 5 is more than or equals to the value of this parameter, flow control is
triggered.
Whether to enable the concentric cell handover algorithm. The concentric cell handover helps to achieve wide
coverage in the underlaid subcell and aggressive frequency reuse in the overlaid subcell and to improve the system
Number of the port through which the DXX is connected to the BSC6900
Whether to connect the power monitoring board
Type of the connection between the NE and EMS or LMT. The connection can be a plain connection or SSL
encryption connection.
Whether the Iur-g common connection is established between the BSC and a co-BSC6900 RNC or an external RNC.
Minimum interval between the two consecutive handover decisions of an MS. The BSC cannot make a handover
decision during the minimum interval.
The twice intra-cell handover events during this interval are considered consecutive handover events.
Whether to perform the PING operation continuously. When the continuous PING operation is performed, the system
sends the PING packets to the specified IP address. You can stop the PING operation by using CTRL + Q.
Transmitted packets
Duration for starting the CPRI Loop test
This parameter specifies whether to allow the BSC6900 to enable or disable the power amplifier of a TRX based on
the traffic volume.
CPU number on a board
Whether to enable the BTS to support CRC4 check
Cell reselection hysteresis. This is one of the parameters used for deciding whether to reselect cells in different
location areas. This parameter can avoid the increase of network signaling traffic due to frequent location update and
Name of the certificate revocation list file
Whether to enable the certificate revocation list
DISABLE: indicating that the certificate revocation list is disabled
Time interval for the BTS resending a channel release message
Number of times the BTS resends a channel release message
Cell Reselect Offset (CRO), indicating a correction of the C2.
Proper setting of this parameter can reduce the number of handover times, helpful for assigning an MS to a better
Threshold of the time for crosstalk detection. Within the threshold, if the call flag continuously appearing in the code
stream is different from the one saved in a transcoder (TC) or a BTS, the TC or the BTS considers that a crosstalk
The field indicates whether the cross-connect path is available. When the cross-path is available, a maximum of four
IP paths exists. The four IP paths are the IP path between the first local IP address and the first peer IP address, the
Output range of the supplementary information contained in the CHR in common user mode. Multiple options can be
selected at the same time.
Rate threshold of bad speech quality in common user mode.
Whether MR is contained in the CHRs in specified user mode
Whether the information about the specified abnormal call end is contained in the CHRs in common user mode.
GSM CS data service downlink factor
CS data path
CS data priority
GSM CS data service uplink factor
Priority of the CS data service. The parameter is used for BSC6900 flow control.
The smaller the value of this parameter, the higher the priority.
Whether handover information is contained in the CHRs in common user mode
Whether the MR before call release is contained in the CHRs in common user mode.
Whether the MR before handover is contained in the CHRs in common user mode.
CHR output mode. In common user mode, the CHRs of all the MSs specified by "CHR Output Range" are output. In
specified user mode, the CHR of a specific MS, which is specified by running the ADD GCSCHRUSER command, is
Area in which CHRs need to be output in common user mode. If this parameter is set to "Output All Records "in
Cells, you need to run the SET GCSCHRSCOPE command to specify the cells whose CHRs are to be output
Whether to output the call history record (CHR)
Type of signaling contained in CHRs
Threshold for starting LAPD link congestion control. This parameter cannot be set too high. If this parameter is set
too high, the signaling link may be congested before congestion control is started. The congestion start and end
Type of the service whose CHR need to be output
GSM CS voice service downlink factor
Whether speech information is contained in the CHRs in specified user mode.
CS voice path
CS voice priority
GSM CS voice service uplink factor
Priority of a speech service in the CS domain. The parameter is used for BSC6900 flow control.
The smaller the value of this parameter, the higher the priority.
Self-healing switch for the Ethernet adapter traffic monitoring
Timer alignment ready. Timer T1 is started after the MTP2 link enters the Aligned Ready state. If one end of the
MTP2 link receives an FISU or MSU message from the peer end within the period of time defined by T1, the MTP2
Timer not aligned. Timer T2 is started at the time that the MTP2 link is set up and begins to transmit the SIO
message. If one end of the MTP2 link receives an SIO, SIN, or SIE message from the peer end with the period of
Timer aligned. Timer T3 is started at the time that the MTP2 link enters the aligned state and starts to transmit SIN
(normal alignment) or SIE (emergency alignment) message. If one end of the MTP2 link receives an SIN or SIE
Timer emergency proving. The two ends of the MTP2 link exchange messages after entering the emergency
verification state. Each end verifies the correctness of the messages sent from the peer end. If the error rate of the
Timer normal proving. The two ends of the MTP2 link exchange messages after entering the normal verification
state. Each end verifies the correctness of the messages sent from the peer end. If the error rate of the messages
Timer sending SIB. If one end of the MTP2 link detects congestion, it sends SIB indications to the peer end at an
interval specified by timer T5. This parameter only applies to the 64 kbit/s links. For the 2 Mbit/s links, the value of
Timer remote congestion. A link is considered broken when the remote congestion duration exceeds the value
specified by timer T6. This parameter only applies to the 64 kbit/s links. For the 2 Mbit/s links, the value of this timer
Timer excessive delay acknowledgement. A link is considered broken if one end of the link does not receive a
verification message from the peer end within the period of time defined by timer T7 after sending a message. This
Timer interval of resending FISU. Timer T9 specifies the interval at which the BSC sends the FISU frames. That is,
the BSC sends an FISU frame every N (N indicates the period of time defined by T9) when the MTP2 link is idle.
Critical threshold of CPU usage. When the CPU usage in "Fast judgement window" reaches or exceeds the
threshold, all active flow control functions are implemented. Otherwise, the corresponding flow control mechanism is
Critical threshold of packet queue usage. When the packet queue usage reaches or exceeds the threshold, all active
flow control functions are implemented.
DPC of the control BSC
Format of the control acknowledge message of the MS. Four access bursts are used to obtain timing advance
without sending polling message; RLC/MAC control block is used to obtain timing advance after sending polling
Control Flag
Number of the cabinet which controls RET antenna.
ControlPort No. of RET antenna. The number of RET antenna which connect to same feed tributary cannot be more
than 6.For GATM boards, the valid value ranges from 0 to 5. For RXU boards, the valid value ranges from 0 to 2.
Number of the slot where the board controlling the RET antenna is located. For SingleRAN BTSs, the valid value
ranges from 0 to 5. For non-SingleRAN BTSs, the valid value ranges from 0 to 23.
Number of the subrack where the BTS board is located
Slot number of the MPU Subsystem for the centralized management of the resources
Number of the BSC6900 slot where the XPU of the control plane is located
Number of the BSC6900 subrack where the XPU of the control plane is located
Configuration rollback control switch that is used to specify whether to support the configuration rollback function
Whether an HO_RQD message contains the Current Channel
C-version number of the BTS software
Period of new file generation.
This is the data file for upgrading board. The data file names of different boards are different.
Number of measurement reports sampled for averaging the signal quality on a speech/data channel. Averaging the
signal quality in multiple measurement reports helps to avoid a sharp signal quality drop due to Rayleigh fading and
Number of measurement reports sampled for averaging the signal strength on a speech/data channel. Averaging the
signal strength in multiple measurement reports helps to avoid a sharp signal level drop due to Rayleigh fading and
Data service supported by the BSC6900. You can set this parameter according to actual requirements.
Whether to limit the operation date of the operator
Date
Unique number of the date range during which to disable the BSC from shutting down the TRX dynamically
Date when the TMU board software is released
Temperature error allowed when the temperature control system adjusts the temperature.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether the primary BCCH is configured on the inner or extra part of an intelligent underlay-overlay (IUO) cell
Index of a same group cell in an enhanced dual band network
Name of a same group cell in an enhanced dual band network
Index type of a same group cell in an enhanced dual band network
DC Lowvoltage Alarm Cabinet No.
DC Lowvoltage Alarm Port No.
DC Lowvoltage Alarm Slot No.
DC Lowvoltage Alarm Subrack No.
DC voltage alarm lower threshold. When the busbar output voltage is lower than the value of this parameter, an
alarm indicating the abnormal busbar voltage is reported.
The BTS reports an alarm if the DC voltage exceeds the value of this parameter.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
The BTS reports an alarm if the DC voltage is lower than the value of this parameter.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
DC voltage alarm upper threshold. When the busbar output voltage is higher than the value of this parameter, an
alarm indicating the abnormal busbar voltage is reported.
This parameter specifies the default pre-converted PDCHs in the dynamic transferable channel pool.
When this parameter is greater than 0, three sub-links are bound to the static PDCH and pre-converted PDCH in a
Timer for delaying a connection release. This parameter is used for delaying the channel deactivation after the active
signaling link is broken. The purpose is to reserve some time for the disconnection that may be repeated. After
The destination entity number uniquely identifies a destination entity.
Description of the operator account
Whether to start the anti-theft equipment of the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Destination IP address
Destination IP address
Destination IP address
Identifies a maintenance point in the maintenance group
Type of the object the BTS is connected to
Type of the object the BTS is connected to. Value range: BTS, BSC6900, and DXX
Slot No. of the subsystem where the Iur-g common connection is established to the co-BSC6900 RNC
Subrack No. of the subsystem where the Iur-g common connection is established to the co-BSC6900 RNC
No. of the subsystem where the Iur-g common connection is established to the co-BSC6900 RNC
ID of the TRX that carries the destination main BCCH
Interval for sending test TRAU frames in the period of class-2 mute detection.Test TRAU frame is sent at the
specified interval till the peer end responds or the timer of "Period of Mute Detection Class 2" expires.
Maximum number of periods in which the local end does not receive BFD packets from the peer end. If the number
of periods in which the local end does not receive BFD packets from the peer end reaches this parameter, the BTS
Switch for Abis Timeslot Detection
Name of the RET antenna
Number of the RET antenna.
Device IP address of the interface board used by the PPP link.
Device IP Address Type
Downlink frequency of the external 3G cell
Number of the slot where the DFCB is installed
Number of the subrack where the DFCB is installed
The default DPC corresponds to the CN of the primary operator.
When only one DPC is configured, this parameter must be set to "YES", indicating that all the calls for the operator
Whether to use the customized port
DEFAULTPORT: indicating that the FTP server uses the default port 21 as a command port and port 20 as a data
Period for reporting differential GPS data
This parameter indicates the IP Address of DHCP Relay Gateway.
DHCP Relay ID
Whether to enable the diesel engine save switch
Whether to allow an MS to report the classmark and whether to hand over the MS from the SDCCH in the frequency
band for the main BCCH to the SDCCH in a different frequency band according to the classmark
Day in the month on which the command can be executed.
Day in the week on which the command can be executed.
The relative path in the working path of the FTP user in the FTP server
Directory of the software to be downloaded
Whether the BSC sends an Assignment Fail message with the cause value of directed retry to the MSC before the
BSC initiates a directed retry procedure
Whether to enable a directed retry. The directed retry is to hand over an MS to a neighboring cell in the same
procedure as the handover. The directed retry is an emergency measure applicable to abnormal traffic peaks in
Whether a cell is a repeater. With simpler functions than a BTS, a repeater is a coverage extension device of a BTS.
It is applied to widely-stretched areas or indoor areas to solve the dead zone problem of BTS coverage. Using
Timer to control the duration in which the BSC prevents the handover of an MS from which the BSC receives the
Disconnect message. If the MS is handed over to a new cell after the MS sends the Disconnect message, the MS
Whether to activate transmit diversity on the common channel of a 3G cell
Delay of transmit diversity when 16QAM is used. Generally, the parameter is applicable to general fading
environments. The transmit diversity can generally bring a gain of 3 dB to 5 dB. The fading conditions vary with the
Delay of transmit diversity when 32QAM is used. Generally, the parameter is applicable to general fading
environments. The transmit diversity can generally bring a gain of 3 dB to 5 dB. The fading conditions vary with the
Delay of transmit diversity when 8PSK is used. Generally, the parameter is applicable to general fading
environments. The transmit diversity can generally bring a gain of 3 dB to 5 dB. The fading conditions vary with the
Whether to support transmitting diversity or four diversity receiving
Minimum interval between two consecutive downlink power control commands
If the downlink receive quality level of an AMR full rate call is greater than this parameter, the call needs to undergo
Huawei power control generation III.
If the downlink receive quality level of an AMR full rate call is smaller than this parameter, the call needs to undergo
Huawei power control generation III.
If the downlink receive quality level of an AMR half rate call is greater than this parameter, the call needs to undergo
Huawei power control generation III.
If the downlink receive quality level of an AMR half rate call is smaller than this parameter, the call needs to undergo
Huawei power control generation III.
ID of the data link connection of the NSVC. It is an interworking parameter which must be consistent on the BSC and
the peer.
If the ratio of downlink flux to uplink flux is greater than or equal to the threshold during the fast flux measurement,
the downlink services takes priority.
Whether the cell supports DLDC
Threshold for downlink edge handover. If the downlink receive level remains less than this threshold for a period of
time, the edge handover is triggered. If the PBGT handover algorithm is enabled, this threshold can be decreased
Filter adjustment factor for downlink power control. Setting this parameter high helps to smooth the filtered values
and to reduce the impact of poor measurement reports on the filtered values. Setting this parameter low helps to
Upper quality threshold for Huawei power control generation III on a full rate call. If the downlink receive quality level
of a full rate call is greater than this threshold, the call needs to undergo Huawei power control generation III.
Lower quality threshold for Huawei power control generation III on a full rate call. If the downlink receive quality level
of a full rate call is smaller than this threshold, the call needs to undergo Huawei power control generation III.
Expanded size of the GPRS RLC window. This parameter is used to expand the size of the GRPS RLC window. The
expanded window size breaks the restrictions of 64 defined in the protocol and reduces the probability of GRPS RLC
Upper quality threshold for Huawei power control generation III on a half rate call. If the downlink receive quality level
of a half rate call is greater than this threshold, the call needs to undergo Huawei power control generation III.
Lower quality threshold for Huawei power control generation III on a half rate call. If the downlink receive quality level
of a half rate call is smallter than this threshold, the call needs to undergo Huawei power control generation III.
Adjustment hysteresis 1 of AMR downlink coding rate (full rate). According to a certain algorithm and the radio quality
indication (RQI) in the call measurement report, the MS and the BTS automatically adjust the current speech coding
Adjustment hysteresis 2 of AMR downlink coding rate (full rate). According to a certain algorithm and the radio quality
indication (RQI) in the call measurement report, the MS and the BTS automatically adjust the current speech coding
Adjustment hysteresis 3 of AMR downlink coding rate (full rate). According to a certain algorithm and the radio quality
indication (RQI) in the call measurement report, the MS and the BTS automatically adjust the current speech coding
Adjustment hysteresis 1 of AMR downlink coding rate (half rate). According to a certain algorithm and the radio
quality indication (RQI) in the call measurement report, the MS and the BTS automatically adjust the current speech
Adjustment hysteresis 2 of AMR downlink coding rate (half rate). According to a certain algorithm and the radio
quality indication (RQI) in the call measurement report, the MS and the BTS automatically adjust the current speech
Adjustment hysteresis 3 of AMR downlink coding rate (half rate). According to a certain algorithm and the radio
quality indication (RQI) in the call measurement report, the MS and the BTS automatically adjust the current speech
Adjustment hysteresis 1 of AMR downlink coding rate (wide band). According to a certain algorithm and the radio
quality indication (RQI) in the call measurement report, the MS and the BTS automatically adjust the current speech
Adjustment hysteresis 2 of AMR downlink coding rate (wide band). According to a certain algorithm and the radio
quality indication (RQI) in the call measurement report, the MS and the BTS automatically adjust the current speech
Threshold for determining whether downlink interference exists. If the downlink level is equal to or greater than
"Interf.of DL Level Threshold" and the downlink quality level is equal to or greater than "Interf.of DL Qual.Threshold",
Threshold for determining whether downlink interference exists. If the downlink level is equal to or greater than
"Interf.of DL Level Threshold" and the downlink quality level is equal to or greater than "Interf.of DL Qual.Threshold",
When the downlink load of a cell is larger than the value of this parameter and is smaller than "2G Cell DL Overload
Congest Thred", the downlink of the cell is in the basic congestion status.
Number of measurement reports sampled for averaging downlink signal strength. A single measurement report may
not reflect the actual network situations accurately. Therefore, the BSC needs to average the measured values in
Lower voice quality threshold associated with the automatic adjustment of the AMR downlink handover threshold.
The value of this parameter must be smaller than or equal to the value of Downlink Long-term FER Target.
Target value of the voice quality automatically adjusted through the downlink threshold of AMR handover
Upper voice quality threshold associated with the automatic adjustment of the AMR handover downlink threshold.
Factor of downlink threshold adjustment. It indicates the linear relation between the threshold adjustment value and
the logarithmic FER.
Maximum step by which to decrease downlink power according to signal strength
Maximum step by which to increase downlink power according to signal strength
When the downlink load of a cell is greater than the value, the downlink of the cell is in the overload congestion
status.
Number of downlink measurement reports that the BSC predicts. The BSC takes a while to confirm the power control
effect of a power control command. Thus, the BSC makes a power control decision based on a measurement report
Quality level threshold for decreasing downlink signal power. If the BTS transmits signals at a quality level less than
this threshold, the BSC decreases the power of the BTS. If (downlink receive level - "MAX Down Adj. PC Value by
Quality level threshold for increasing downlink signal power. If the BTS transmits signals at a quality level greater
than this threshold, the BSC increases the power of the BTS. If (downlink receive level + "MAX Up Adj. PC Value by
Number of measurement reports sampled for averaging downlink signal quality. A single measurement report may
not reflect the actual network situations accurately. Therefore, the BSC needs to average the measured values in
During downlink power control, if the downlink receive quality level is equal to or greater than "DL Qual, bad Trig
Threshold", "DL RX_LEV Upper Threshold" is increased by "DL Qual. Bad UpLEVDiff" to further increase the
During downlink power control, if the downlink receive quality level is equal to or greater than "DL Qual, bad Trig
Threshold", "DL RX_LEV Upper Threshold" is increased by "DL Qual. Bad UpLEVDiff" to further increase the
Downlink quality threshold for emergency handover. This parameter is represented as the product of 10 and a quality
level that ranges from 0 to 7. The emergency handover can be triggered only when the downlink receive quality of an
Downlink quality limit for emergency handover in an AMR full rate call. The value of this parameter corresponds to
the quality levels (0 to 7) multiplied by 10. An emergency handover can be triggered only when the downlink
Downlink quality limit for emergency handover in an AMR half rate call. The value of this parameter corresponds to
the quality levels (0 to 7) multiplied by 10. An emergency handover can be triggered only when the downlink
This parameter specifies the downlink signal strength factor multiplied by 10 during the calculation of the downlink
power control step. The downlink signal strength factor is a coefficient indicating how much the signal strength is
Length of the exponential filter for downlink signal strength. A single measurement report may not reflect the actual
network situations accurately. Therefore, the BSC needs to filter the measured values in several successive
Upper receive level threshold for downlink power control. If the downlink receive level is greater than this threshold,
the power of the downlink signal needs to be decreased.
Lower receive level threshold for downlink power control. If the downlink receive level is smaller than this threshold,
the power of the uplink signal needs to be increased.
Length of the slide window filter for downlink signal strength. A single measurement report may not reflect the actual
network situations accurately. Therefore, the BSC needs to filter the measured values in several successive
This parameter specifies the downlink quality level factor multiplied by 10 during the calculation of the downlink
power control step. The downlink quality level factor is a coefficient indicating how much the quality level is
Length of the exponential filter for downlink signal quality. A single measurement report may not reflect the actual
network situations accurately. Therefore, the BSC needs to filter the measured values in several successive
Length of the slide window filter for downlink signal quality. A single measurement report may not reflect the actual
network situations accurately. Therefore, the BSC needs to filter the measured values in several successive
A power control step cannot exceed the step computed according to "III DL RexLev Protect Factor" and "III DL
RexQual Protect Factor".
A power control step cannot exceed the step computed according to "III DL RexLev Protect Factor" and "III DL
RexQual Protect Factor".
Upper threshold for downlink signal strength
If the downlink received signal level is greater than this threshold, a power decrease is computed. Then, the power is
Lower threshold for downlink signal strength
If the downlink received signal level is less than this threshold, a power increase is computed. Then, the power is
Time interval between sending of the Packet Uplink Ack/Nack message and setup of the DL TBF. After receiving the
Packet Uplink Ack/Nack message (FAI = 1), the MS releases the UL TBF and starts to monitor CCCH. In this case, if
Interval for resending downlink test messages
Number of times of the BSC6900 resending downlink test messages after the downlink test function is enabled. If the
BSC6900 does not receive any response message from the MS at the preset interval, the BSC6900 releases the
Adjustment threshold 1 of AMR downlink coding rate (full rate). According to a certain algorithm and the RQI in the
call measurement report, the MS and the BTS automatically adjust the current speech coding and decoding rate. The
Adjustment threshold 2 of AMR downlink coding rate (full rate). According to a certain algorithm and the RQI in the
call measurement report, the MS and the BTS automatically adjust the current speech coding and decoding rate. The
Adjustment threshold 3 of AMR downlink coding rate (full rate). The adjustment thresholds and the hysteresis of
coding rate must meet the following conditions: AMR Coding Rate adj.th (n) < AMR Coding Rate adj.th (n + 1), n = 1
Adjustment threshold 1 of AMR downlink coding rate (half rate). According to a certain algorithm and the RQI in the
call measurement report, the MS and the BTS automatically adjust the current speech coding and decoding rate. The
Adjustment threshold 2 of AMR downlink coding rate (half rate). According to a certain algorithm and the RQI in the
call measurement report, the MS and the BTS automatically adjust the current speech coding and decoding rate. The
Adjustment threshold 3 of AMR downlink coding rate (half rate). According to a certain algorithm and the RQI in the
call measurement report, the MS and the BTS automatically adjust the current speech coding and decoding rate. The
Adjustment threshold 1 of AMR downlink coding rate (wide band). According to a certain algorithm and the RQI in the
call measurement report, the MS and the BTS automatically adjust the current speech coding and decoding rate. The
Adjustment threshold 2 of AMR downlink coding rate (wide band). According to a certain algorithm and the RQI in the
call measurement report, the MS and the BTS automatically adjust the current speech coding and decoding rate. The
MDU board number when the antenna pass of downlink tributary A is selected
MDU board number when the antenna pass of downlink tributary B is selected
Clock domain required by the slave side in the 1588V2 protocol. This parameter is valid when the 1588CLK type is
configured.
Coding scheme of the default GPRS downlink. Dynamic adjustment coding: the coding scheme used during initial
access transmission. If the downlink uses the fixed coding scheme, the TBF uses the fixed coding scheme.
Default coding scheme of the downlink EDGE link. If the downlink adopts the dynamic adjustment coding scheme,
this parameter can be used to set the coding scheme for transmission during initial access. If the downlink uses the
Default coding scheme used on the downlink EGPRS2-A link. If the downlink uses the dynamic coding scheme, this
parameter specifies the coding scheme that is used for the transmission in initial access. If the downlink uses the
Fixed coding scheme that is used on the downlink EGPRS2-A link. If the downlink uses the fixed coding scheme, this
parameter can be set MSC1-4, MSC7-8 or DAS5-12.. If the downlink uses the dynamic coding scheme, this
Adjustment mode of the downlink GPRS link coding scheme. If the fixed coding scheme is used, this parameter is
set to a value ranging from CS1 to CS4. If the dynamic coding scheme is used, this parameter is set to UNFIXED.
Coding scheme of the downlink EDGE link. If the downlink uses the fixed coding scheme, this parameter is set to a
value ranging from MCS1 to MCS9. If the downlink uses the dynamic adjustment coding scheme, this parameter is
Whether to allow BTS power control
Whether to prohibit sending point-to-point short messages. If necessary, this parameter is used for controlling
whether to send downlink short messages from a specific cell so as to ensure sufficient radio channel resources for
Delay of releasing the downlink TBF. After the last downlink RLC data block is transmitted on the network side and
all the transmitted downlink data blocks are received, the MS is not informed to stop this downlink TBF. Instead, the
Retransmission threshold when the coding mode of the downlink TBF is changed from CS2 to CS1. When the
downlink TBF retransmission rate is greater than or equals to this value, the coding mode of the TBF is changed
Retransmission threshold when the coding mode of the TBF is changed from CS3 to CS2. When the TBF
retransmission rate is greater than or equals to this value, the coding mode of the TBF is changed from CS3 to CS2.
Retransmission threshold when the coding mode of the downlink TBF is changed from CS4 to CS3. When the
downlink TBF Retransmission rate is greater than or equals to this value, the coding mode of the TBF is changed
Retransmission threshold when the coding mode of the downlink TBF is changed from CS1 to CS2. When the TBF
retransmission rate is less than or equals to this value, the coding mode of the TBF is changed from CS1 to CS2.
Retransmission threshold when the coding mode of the TBF is changed from CS2 to CS3. When the downlink TBF
retransmission rate is less than or equals to CS2 to CS1, the coding mode of the TBF is changed from CS2 to CS3.
Retransmission threshold when the coding mode of the downlink TBF is changed from CS3 to CS4. When the
downlink TBF retransmission rate is less than or equals to this value, the coding mode of the downlink TBF is
Door status alarm switch
Dual-antenna gain used to estimate the downlink power during assignment
As an integer, the DSP code can be expressed by a decimal digit or a hexadecimal digit. If the DSP code is
expressed by a hexadecimal digit, H' is added before the number.
DSP code expressed in the format of segments 8-8-8
As a key field for identifying the block of A interface CIC status, it indicates the DPC group index of the circuit ID of
the A interface to be blocked.
Index of the DPC group. see "ADD GCNNODE" command.
Index of a DPC group.
When multiple DPCs or one DPC serves as a logical entity, this logical entity is called a DPC group.
DSP type.
STP: indicates the signaling transfer point.
The DSP index uniquely identifies a DSP.
Iur-g DPC index of a neighboring RNC
Maximum signal level difference between the neighbor cell and the serving cell for triggering directed retry
Whether to optimize the call drops resulting from Abis territorial link fault. The value 0 means "optimize" and 1 means
"not optimize". If the value of this parameter is 0, the call drops resulting from this cause are not brought into the
Whether to optimize the call drops resulting from connection failure (handover access failure). The value 0 means
"optimize" and 1 means "not optimize". If the value of this parameter is 0, the call drops resulting from this cause are
Whether to optimize the call drops resulting from connection failure, operation and maintenance (OM) intervention.
The value 0 means "optimize" and 1 means "not optimize". If the value of this parameter is 0, the call drops resulting
Whether to optimize the call drops resulting from a connection failure except for handover access failure, OM
intervention, radio link failure, and unavailability of radio resources. The value 0 means "optimize" and 1 means "not
Whether to optimize the call drops resulting from connection failure (radio link failure). The value 0 means "optimize"
and 1 means "not optimize". If the value of this parameter is 0, the call drops resulting from this cause are not
Whether to optimize the call drops resulting from connection failure (unavailability of radio resources). The value 0
means "optimize" and 1 means "not optimize". If the value of this parameter is 0, the call drops resulting from this
Whether to optimize the call drops resulting from equipment fault. The value 0 means "optimize" and 1 means "not
optimize". If the value of this parameter is 0, the call drops resulting from this cause are not brought into the statistics
Whether to optimize the call drops resulting from error indication (unsolicited DM response). The value 0 means
"optimize" and 1 means "not optimize". If the value of this parameter is 0, the call drops resulting from this cause are
Whether to optimize the call drops resulting from error indication (sequence error). The value 0 means "optimize" and
1 means "not optimize". If the value of this parameter is 0, the call drops resulting from this cause are not brought
Whether to optimize the call drops resulting from error indication (T200 timeout). The value 0 means "optimize" and 1
means "not optimize". If the value of this parameter is 0, the call drops resulting from this cause are not brought into
Whether to optimize the call drops resulting from forced handover failure. The value 0 means "optimize" and 1
means "not optimize". If the value of this parameter is 0, the call drops resulting from this cause are not brought into
Whether to optimize the call drops resulting from incoming-BSC handover timeout. The value 0 means "optimize"
and 1 means "not optimize". If the value of this parameter is 0, the call drops resulting from this cause are not
Whether to optimize the call drops resulting from outgoing internal inter-cell handover timeout. The value 0 means
"optimize" and 1 means "not optimize". If the value of this parameter is 0, the call drops resulting from this cause are
Whether to optimize the call drops resulting from intra-cell handover timeout. The value 0 means "optimize" and 1
means "not optimize". If the value of this parameter is 0, the call drops resulting from this cause are not brought into
Whether to optimize the call drops resulting from no MS measurement reports for a long time. The value 0 means
"optimize" and 1 means "not optimize". If the value of this parameter is 0, the call drops resulting from this cause are
Whether to optimize the call drops resulting from outgoing-BSC handover timeout. The value 0 means "optimize" and
1 means "not optimize". If the value of this parameter is 0, the call drops resulting from this cause are not brought
Whether to optimize the call drops resulting from release indications. The value 0 means "optimize" and 1 means
"not optimize". If the value of this parameter is 0, the call drops resulting from this cause are not brought into the
Whether to optimize the call drops resulting from resource check. The value 0 means "optimize" and 1 means "not
optimize". If the value of this parameter is 0, the call drops resulting from this cause are not brought into the statistics
If the duration for buffering the data in queue 0 is more than or equals to the value of this parameter, the subsequent
packets added to queue 0 are discarded.
If the duration for buffering the data in queue 1 is more than or equals to the value of this parameter, the subsequent
packets added to queue 1 are discarded.
If the duration for buffering the data in queue 2 is more than or equals to the value of this parameter, the subsequent
packets added to queue 2 are discarded.
If the duration for buffering the data in queue 3 is more than or equals to the value of this parameter, the subsequent
packets added to queue 3 are discarded.
If the duration for buffering the data in queue 4 is more than or equals to the value of this parameter, the subsequent
packets added to queue 4 are discarded.
If the duration for buffering the data in queue 5 is more than or equals to the value of this parameter, the subsequent
packets added to queue 5 are discarded.
This parameter specifies the interval at which the power of a TRX is continually decreased.
This parameter specifies the delay time before decreasing the power of the TRXs.
This parameter specifies the step by which the power of a TRX is decreased at a time.
Whether to support the discontinuous reception mechanism (DRX). To reduce the power consumption, the DRX is
introduced into the GSM Specification. MSs supporting the DRX can consume less power to receive interested
Duration of the timer for entering the DRX mode. DRX is the parameter in the cell broadcast message. It indicates
non-continuous receiving mode. When the MS is switched from the packet transmission mode to the idle mode, the
Whether to start the dehumidification equipment of the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Number of the E1T1 port for bearing the PPP link
Number of the E1T1 port for bearing the PPP link
The DSCP is a field of the IP data packet. It is used to assign the differentiated service to the communication
networks. The DSCP code is used to label each data packet on the network and allocate the corresponding service
Service code of the PING command, used to identify the PING command
Differentiated service code is used to identify the service priority of the user.
DSCP to be contained in the header of an IP packet. According to this parameter, the router provides differentiated
services for packet streams. If this parameter is greater, the service level is higher. This parameter is valid only when
Duration for recovering all the DSPs. This timer is started when the first DSP is recovered. When all the DSPs of the
local subrack are recovered or the timer expires, the timer is stopped. The cells are distributed on the recovered
Number of the DSP. If you do not specify this parameter, all DSPs are specified.
Meanings:DSP No.
Value range:0~21
Number of the DSP where the alarm is generated
Number of the DSP in the DPU board
Target DSP number
This parameter specifies the value of the timer set to wait the fault recovery before the cell redistribution on the DSP.
When a fault is detected on a DSP, this timer starts. If the fault is recovered before the timer expires, the cells on the
Whether daylight saving time has to be used
Name of the destination file
Destination IP address
Destination IP address of BFD Session.
Destination IP address
Subnet mask
Subnet mask of BTS Route.
Destination of timeslot cross
Target timeslot mask
Threshold of the load in the target cell for the directed retry. Only a cell whose load is lower than or equal to this
threshold can be selected as a candicate target cell.
Type of the DRX supporting the VGCS service. An MS reads the NCH only when a new notification message of
group call arrives. This helps save power of the MS. This parameter is mandatory for a SAGEM MS.
Downlink TRX index number of the newly added board
Index number of the downlink tributary
TRX board pass number connected with the downlink tributary
TRX board pass number connected with the downlink tributary
Number of the slot where the TRX board that connects to downlink tributary is located
Number of the slot where the TRX board that connects to downlink tributary is located
Number of the subrack where the TRX board that connects to downlink tributary is located
Number of the subrack where the TRX board that connects to downlink tributary is located
Whether a BTS randomizes the dummy bits in all the signaling messages that the BTS sends to an MS. That is,
dummy bits are randomized rather than filled on the basis of 0x2B.
The duplex mode of FE port is duplex or half-duplex.
Duration for starting the BTS test
Duration for starting the TRX idle timeslot test
Duration for starting the BTS test
Duration for starting the TRX idle timeslot test
Downlink multiplex threshold of dynamic channel conversion. When the subscriber number on the channel reaches
the value (threshold/10), the dynamic channel conversion is triggered. We recommand that the value of "Downlink
An MS can be used to test the Um interface software synchronization only when the DL signal strength after the
power control compensation in the test cell and the observed cell is higher than this limit.
Number of a DXX. It is unique in one BSC6900 and uniquely identifies a DXX.
Number of a DXX. It is unique in one BSC6900 and uniquely identifies a DXX.
Number of the upper DXX port
Time to wait for releasing the dynamic channel after the TBF on the dynamic channel is released. When all the TBFs
on the channel are released, the dynamic channel is not released at once. Instead, the timer is started when the
Mode of preempting the dynamic channel for the CS domain and PS domain. Only the channel configured in the
TCH/F mode can be preempted.
Number of full-rate TCHs reserved for the CS domain. This parameter is valid only when "Level of Preempting
Dynamic Channel" is set to LEVEL1 or LEVEL2.
This parameter specifies whether to allow the BSC6900 to enable the TRX Intelligent Shutdown feature on a cell.
Whether to enable the cell to support dynamic transmit diversity or dynamic PBT
Duration for the test in E1 mode
Number of the E1 port. For the BTS3012, BTS3012AE, BTS3012 II and the UTRP board in SingleRAN BTSs, the
number can be a value from 0 to 7. For other BTSs, the number can be a value from 0 to 3.
Number of the E1 port on the BTS connected to the BSC.
Type of the transmission board
E1/T1 port number
Number of the E1/T1 port from which the BTS extracts the transport clock. This parameter is valid only when the
clock type is set to IP_TRANSFER.
Number of the port extended by the backboard TOP communication mechanism of the BTS. The TOP relation can
be configured between the port on the BTS board panel and the port on the BTS backplane, thus extending the
Type of the E1/T1 from which the BTS extracts the transport clock. This parameter is valid only when the clock type
is set to IP_TRANSFER.
Peer IP address to be checked. The input address (CHKIPADDR) must be the address (regardless of the network
segment address or host address of the peer address) in the network segment specified by the (PEERIPADDR,
As a performance counter for 3G cells, Ec/No indicates the ratio of the energy per received chip to the spectral noise
power density.
Threshold for determining the layer of the 3G neighbor cell. If the Ec/No of the 3G neighbor cell is less than this
threshold, the neighbor cell is set to the lowest layer (layer 5).
The early classmark sending control (ECSC) parameter specifies whether the MSs in a cell use early classmark
sending. After a successful immediate assignment, the MS sends additional classmark information to the network as
End serial number of the alarm record
Date when the scheduled task is stopped
End date of the alarm record. By default, the end date is 2037-12-31.
End date of the alarm record. By default, the end date is 2037-12-31.
End date
End date of the daylight saving time
According to the P/N rule, if the conditions for the handover between the subcells of an enhanced dual-frequency
network are met during P of N measurements, the handover is triggered.
According to the P/N rule, if the conditions for the handover between the subcells of an enhanced dual-frequency
network are met during P of N measurements, the handover is triggered.
If the current system flow control level is greater than this parameter, the handover between the underlaid and
overlaid subcells due to low or high load in the underlaid subcell is not allowed. System flux thresholds correspond to
Whether the current cell supports EDGE
According to the P/N rule, if a neighbor cell meets the conditions for selecting the neighbor cell for edge handover in
P of N measurement reports, the edge handover to the neighbor cell is triggered.
According to the P/N rule, if a neighbor cell meets the conditions for selecting the neighbor cell for edge handover in
P of N measurement reports, the edge handover to the neighbor cell is triggered.
According to the P/N rule, if the conditions for edge handover are met in P of N measurement reports, the handover
is triggered.
According to the P/N rule, if the conditions for edge handover are met for P seconds within N seconds, the handover
is triggered.
According to the P/N rule, if the conditions for edge handover are met in P of N measurement reports, the handover
is triggered.
According to the P/N rule, if the conditions for edge handover are met for P seconds within N seconds, the handover
is triggered.
Effect Immediately Flag(reserve)
Whether to support the 11-bit EGPRS access request
Whether the current cell supports EGPRS2-A
Used for EDGE 8PSK transmission quality statistics. If MEAN_BEP is less than or equals to this threshold, the
transmission quality is regarded to be deteriorated. MEAN_BEP indicates the average error code rate in one
Used for EDGE GMSK transmission quality statistics. If MEAN_BEP is less than or equals to this threshold, the
transmission quality is regarded deteriorated. MEAN_BEP indicates the average error code rate in one measurement
Type of the end date. "WEEK" indicates that the end date is a weekday. "DATE" indicates that the end date is a
month day. "DATEWEEK" indicates the end date is expressed by a combination of weekday and month day.
Priority level of an emergency call. If this parameter is set to 15, the functions of reserving TCHs for emergency calls
and preempting TCHs are not enabled. If the two functions need to be enabled, set this parameter to a value from 1
Whether to verify the centralized signaling link in the case of the link establishment. ON: emergency verification, that
is, the verification is not required. OFF: non emergency verification, that is, the verification is required during the
Error emit threshold.
Differentiated service code of the specified EML
Whether to allow the function of enhanced multi-level precedence and preemption (eMLPP). With the eMLPP
function enabled, the network can use different policies such as queuing, preemption, or directed retry based on the
Indicating whether the eMLPP function is enabled in a cell and indicating the eMLPP priority of the cell. From high to
low, the priorities are A, B, 0, 1, 2, 3, 4 and No Priority. No Priority is the lowest.
Whether to include the eMLPP Priority information element in the Paging Command message over the Abis interface
when "Allow eMLPP" is set to YES and the eMLPP flag in the Bitmap information element of the Paging message
Service priority of the specified EML
Service priority of the extension maintenance link (EML).0 is the highest priority.
Specified EML Vlan Id
Month on which DST ends
IP address of the NE management system
Whether to enable the fallback function for the BTS
Whether to enable the power supply of the TMA
Encryption algorithm supported by the BSS side
Encryption mode used when the NE serves as the FTP client
AUTO: indicating that the FTP client automatically selects the encryption mode
Encryption mode supported when the NE serves as the FTP server
AUTO: indicating that the FTP client automatically selects the encryption mode
Whether to enable end-to-end user tracing for the BSC. If this parameter is set to YES, the BSC starts end-to-end
user tracing after the BSC receives the MSC Invoke Trace or BSS Invoke Trace message from the MSC.
End number of the alarm record
It indicates the end CIC of the A interface CIC segment. When operation mode is set to OPC index, DPC group
index, BSC ID, or CIC, the parameter is mandatory.
It indicates the end CIC of the Pb interface CIC segment. If the search object mode is set to search by the specified
range, the parameter is mandatory.
This parameter specifies the end date of a period during which the TRX Intelligent Shutdown feature is disabled.
If the ambient temperature reaches the value of this parameter, the heater is shut down.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
This parameter specifies the end month of a period during which the TRX Intelligent Shutdown feature is disabled.
Number of the end sub-timeslot
This parameter specifies the time for dynamically disabling the TRX Intelligent Shutdown feature each day.
It indicates the end CIC of the Ater interface CIC segment.
It indicates the end CIC of the A interface CIC segment. When Operation mode is set to subrack No., slot No., port
No., or CIC, the parameter is mandatory.
Number of the end timeslot
Status of the scheduled task. This parameter determines whether to start the scheduled task.
Status of the scheduled subtask to be added
If the load of the underlaid subcell is greater than this threshold, certain calls in the underlaid subcell are handed over
to the overlaid subcell to balance the traffic between the overlaid and underlaid subcells.
Whether to support PS downlink MAC back pressures in GSM. When the buffer is overflowed, the L2 transmission
rate is limited if "User Plane DL Flow Ctrl Switch" is "ON". Thus, the data blocks are not lost. If "User Plane DL Flow
Whether to enable the enhanced concentric cell algorithm in a concentric cell.
If a cell supports the enhanced concentric cell function, when an overlaid-to-underlaid handover or an underlaid-to-
If all the calls in the overlaid subcell are handed over to the underlaid subcell when the channel seizure ratio of the
underlaid subcell is less than "En Iuo Out Cell Low Load Thred", the BSC load increases sharply. In this case, the
Signal level step for the hierarchical load-based handover from the overlaid subcell to the underlaid subcell
If the load of the underlaid subcell is less than this threshold, certain calls in the overlaid subcell are handed over to
the underlaid subcell to balance the traffic between the overlaid and underlaid subcells.
When this parameter is set to "ON", if there are no available Abis transmission resources, a high-priority user can
preempt the transmission resources of a low-priority user. If the preemption succeeds, a call drop occurs at the low-
When this parameter is set to "ON", if there are no available Abis transmission resources, the BSC6900 starts the
queuing procedure for the services to wait for available transmission resources.
If the load of the underlaid subcell is greater than this threshold, the period of the load-based handover from the
underlaid subcell to the overlaid subcell, "UL Subcell Load Hierarchical HO Periods", is decreased by "MOD Step
Whether to enable the cell to centralize two busy half rate TCHs in different timeslots into one timeslot through
handover and then to combine the two idle half rate TCHs in the other timeslot into one full rate TCH dynamically
Type of the M3UA local entity. For details about the ASP and IPSP, see RFC4666.
M3UA_ASP: suggested to use when there is a signaling transfer point (STP) between the local entity and the
Type of the destination entity. For details, see RFC4666.
M3UA_ASP: suggested to use when there is a signaling transfer point (STP) between the local entity and the
Initial signal level used to compute the handover zone for an MS during the hierarchical load-based handover from
the underlaid subcell to the overlaid subcell of the enhanced concentric cell
Whether to enable the enhanced packet loss concealment (EPLC) function
Return code of the command. If this parameter is specified, only the corresponding record is displayed. If this
parameter is not specified, the return code is not considered.
Whether to disable emergency calls. For the MSs of access levels 0 to 9, if the value of this parameter is NO,
emergency calls are enabled. For the MSs of access levels 11 to 15, emergency calls are disabled only when the
Error-frame alarm threshold
Error-frame detect switch
Differentiated service code of the specified ESL
Service priority of the ESL
Priority of a service running over an extended signaling link (ESL). ESLs are used for more reliably transmitting
important signaling messages.0 is the highest priority.
Specified ESL Vlan Id
End synchronization number of the alarm record
Timer for the BSC waiting for an Establish Indication message after sending an Immediate Assignment message. If
T3101 expires before the BSC receives an Establish Indication message, the BSS releases the seized SDCCH.
Whether to add the TA value to a complete layer-3 message to provide the LCS function on the A interface
When the OML is switched to a port where the connection is successfully established, the switchover cannot be
performed over a certain period of time, which is specified as ring II rotating penalty time. In this manner, frequent
End time of DST
The operation time of the log record is prior to this time. If this parameter is not specified, the end time is not limited.
Time when the scheduled subtask is stopped. If the time mode is set to "DAILY_T", "WEEKLY_T", or
"MONTHLY_T", you should set this parameter.
Execution mode of the commands
1. ONE_BY_ONE: indicating that the commands are executed one by one according to the execution sequence.
The operation time of the log record is prior to this time. If this parameter is not specified, the end time is not limited.
End time of the alarm record. By default, the end time is 23:59:59.
End time of the alarm record. By default, the end time is 23:59:59.
End date and time of a broadcast message. This is a key parameter for identifying a simple cell broadcast message.
You can use "DSP GSMSCB" to query and obtain the value of this parameter.
End date of the user operation. Input format: YYYY&MM&DD
End time
Type of the log to be queried. The result is displayed by the specified type.
End time of the user operation. The input format of this parameter is HH&MM&SS.
Weekday on which DST ends
Sequence of the end week of DST
Upper limit of extended output analog signal 1. If "Sensor Type of External Analog 1" is set to VOLTAGE, the unit of
this parameter is V; if "Sensor Type of External Analog 1" is set to CURRENT, the unit of this parameter is A.
Lower limit of extended output analog signal 1. If "Sensor Type of External Analog 1" is set to VOLTAGE, the unit of
this parameter is V; if "Sensor Type of External Analog 1" is set to CURRENT, the unit of this parameter is A.
Sensor type of extended analog signal 1
Maximum measurement range of extended analog signal 1. If "Sensor Type of External Analog 1" is set to
VOLTAGE, the unit of this parameter is V; if "Sensor Type of External Analog 1" is set to CURRENT, the unit of this
Minimum measurement range of extended analog signal 1. If "Sensor Type of External Analog 1" is set to
VOLTAGE, the unit of this parameter is V; if "Sensor Type of External Analog 1" is set to CURRENT, the unit of this
Upper limit of extended output analog signal 2. If "Sensor Type of External Analog 2" is set to VOLTAGE, the unit of
this parameter is V; if "Sensor Type of External Analog 2" is set to CURRENT, the unit of this parameter is A.
Lower limit of extended output analog signal 2. If "Sensor Type of External Analog 2" is set to VOLTAGE, the unit of
this parameter is V; if "Sensor Type of External Analog 2" is set to CURRENT, the unit of this parameter is A.
Sensor type of extended analog signal 2
Maximum measurement range of extended analog signal 2. If "Sensor Type of External Analog 2" is set to
VOLTAGE, the unit of this parameter is V; if "Sensor Type of External Analog 2" is set to CURRENT, the unit of this
Minimum measurement range of extended analog signal 2. If "Sensor Type of External Analog 2" is set to
VOLTAGE, the unit of this parameter is V; if "Sensor Type of External Analog 2" is set to CURRENT, the unit of this
Upper limit of extended output analog signal 3. If "Sensor Type of External Analog 3" is set to VOLTAGE, the unit of
this parameter is V; if "Sensor Type of External Analog 3" is set to CURRENT, the unit of this parameter is A.
Lower limit of extended output analog signal 3. If "Sensor Type of External Analog 3" is set to VOLTAGE, the unit of
this parameter is V; if "Sensor Type of External Analog 3" is set to CURRENT, the unit of this parameter is A.
Sensor type of extended analog signal 3
Maximum measurement range of extended analog signal 3. If "Sensor Type of External Analog 3" is set to
VOLTAGE, the unit of this parameter is V; if "Sensor Type of External Analog 3" is set to CURRENT, the unit of this
Minimum measurement range of extended analog signal 3. If "Sensor Type of External Analog 3" is set to
VOLTAGE, the unit of this parameter is V; if "Sensor Type of External Analog 3" is set to CURRENT, the unit of this
Upper limit of extended output analog signal 4. If "Sensor Type of External Analog 4" is set to VOLTAGE, the unit of
this parameter is V; if "Sensor Type of External Analog 4" is set to CURRENT, the unit of this parameter is A.
Lower limit of extended output analog signal 4. If "Sensor Type of External Analog 4" is set to VOLTAGE, the unit of
this parameter is V; if "Sensor Type of External Analog 4" is set to CURRENT, the unit of this parameter is A.
Sensor type of extended analog signal 4
Maximum measurement range of extended analog signal 4. If "Sensor Type of External Analog 4" is set to
VOLTAGE, the unit of this parameter is V; if "Sensor Type of External Analog 4" is set to CURRENT, the unit of this
Minimum measurement range of extended analog signal 4. If "Sensor Type of External Analog 4" is set to
VOLTAGE, the unit of this parameter is V; if "Sensor Type of External Analog 4" is set to CURRENT, the unit of this
Whether it is a SoLSA exclusive access cell. If it is a SoLSA exclusive access cell, only the MS subscribing the
Localised Service Area (LSA) can access this cell.
Threshold for the rate of the number of bad frames to the total number of TRAU frames. If the bad frame rate
exceeds this threshold within the "Period of Mute Detection Class1", mute speech may be detected. The setting of
Received signal strength at an MS expected in power forecast, which helps to compute the initial transmit power of
the BTS
Received signal strength at the BTS expected in power forecast, which helps to compute the initial transmit power of
an MS
ID of the cell. The cell ID cannot conflict with other cell IDs in the BSC6900. The cells in the BSC are numbered
sequentially.
Name of the cell
ID of the cell. The cell ID cannot conflict with other cell IDs in the BSC. The cells in the BSC are numbered
sequentially.
Name of the cell
Index of the cell in the adjacent BSC
Name of the cell in the adjacent BSC
Whether to support the downlink throughput enhancement function of the dual timeslot cell. When this switch is
turned on, the system can allocate the packet downlink channel of the odd number timeslot of dual timeslot bearer of
Whether to enable alarm extension input for the BTS
Whether the network requires an MS to send an extension measurement report
Time interval between two extension measurement reports
Type of an extension measurement report.
There are three types of extension measurement reports: type 1, type 2, and type 3.
Whether a cell is an extension cell.
A double-timeslot extension cell regards an additional TDMA frame as access delay extension. In theory, the
Whether to send the Dummy message during the deactivated period of the extended uplink TBF
Interval of sending a paging message or notification message on the FACCH. Messages on the FACCH are sent in
the mode of speech frame stealing. A large number of consecutive stolen speech frames may affect the voice quality
Whether to allow sending notification messages on the FACCH. If the value of this parameter is YES, an MS
engaged in a point-to-point call can receive a notification message for a group call. You can interrupt the existing call
Whether to allow sending paging messages on the FACCH. If the value of this parameter is YES, an MS can receive
a paging message on the group call channel. You can leave the group call and respond to the paging message.
Activation factor switch
If this parameter is set to ON, the BSC assigns the channels in the TRXs of the cell in a polling manner. Therefore,
each TRX has an even chance to be used. In this way, the connection between the TRX and the RF can be checked
Penalty signal level imposed on a target cell to which the handover fails due to congestion or poor radio quality. This
penalty helps to prevent the MS from making a second handover attempt to the target cell.
Continuous speed adjustment
Discrete speed adjustment
Duty ratio-based speed adjustment
Fan adjustment mode
Type of the fan
Fan adjustment mode
Type of the fan box
After a channel request message is received, the type of the channel needs to be specified. In this case, if the
threshold of the load on the TCH in the current cell is smaller than the Fast Call Setup TCH Usage Threshold and the
Ring II function switch. The parameter should be set to "YES" when the ring II function is enabled.
Whether to enable the memory self-check and self-healing function
Whether to send and process the flow control frame on the physical layer. The setting of this parameter must be
negotiated with that on the interconnected side.
If the parameter is set to "YES", it indicates that some data packets are discarded to ensure the basic functions of
the BTS are not affected when the FE port is overloaded. After the port is not overloaded, the flow control is stopped.
Threshold for stopping RSL flow control. If the occupancy of the LAPD queue is less than this threshold, the
BSC6900 stops flow control.
Flow control parameter index
Flow control parameter index
Flow control parameter index
Flow control parameter index
Flow control parameter index
Flow control parameter index
Flow control parameter index
Cabinet No. of the parent BTS
Cabinet No. for the port of the father BTS
Threshold for starting RSL flow control. If the occupancy of the LAPD queue is greater than this threshold, the
BSC6900 starts flow control.
CRC verification mode of PPP link.
CRC verification mode of MP link.
Flow control switch. Other switches are valid only when "Flow control switch" is "ON".
Float charging voltage. Float charging compensates the discharged capacity of the battery so that the battery can be
charged to full voltage indefinitely. The value of this parameter is slightly lower than the even charging voltage. See
Input mode of the BA lists.
AUTO: In this mode, the system fills in the BA1 and BA2 lists according to neighboring relations of cells.
This parameter indicate whether to generate the FDD BA2 table automatically according to neighbor cell relations or
to input the FDD BA2 table manually
Offset of a FDD cell report.
When the priority of a 3G cell is sequenced, the value of this parameter be added to the receive level of the 3G cell
Threshold of a FDD cell report.
When the receive level value in the measurement report of a 3G cell exceeds the value of this parameter, the
Diversity indication of a 3G cell. This parameter indicates whether the transmit diversity mode on the common
channel in a cell is activated.0 means No,1 means Yes.
Downlink frequency number that an MS in the connected mode retrieves from the 3G neighboring cell list. The
numbers are sent through system message 2QUATER/MI. The value ranges of frequency numbers vary with
Minimum Ec/No of the 3G FDD cell candidate
Number of UTRAN FDD cells that should be included in measurement report
This parameter specifies one of the parameters for FDD cell reselection.
A FDD cell becomes a candidate cell if all the following conditions are met for five consecutive seconds:
Offset of the minimum threshold for Ec/No during a FDD cell reselection.
A FDD cell becomes a candidate cell if all the following conditions are met for five consecutive seconds:
This parameter specifies one of the thresholds of the signal level for 3G cell reselection.
A FDD cell becomes a candidate cell if all the following conditions are met for five consecutive seconds:
This parameter specifies whether Ec/No or RSCP is used for the measurement report on a FDD cell. Ec/No stands
for the signal-to-noise ratio. RSCP stands for the received signal code power.
Minimum level threshold of UTRAN cell reselection. During the cell reselection decision from a GSM cell to a FDD
cell, this parameter is used to calculate the RSCP threshold of the target cell.
Minimum RSCP of the 3G FDD cell candidate
Scrambling code of a 3G cell, used for distinguishing MSs or cells. Scrambling codes are used after spreading.
Therefore, the bandwidth of a signal is not changed. Instead, signals from different sources are differentiated.
Number of CPU usage sampling times for fast judgment. The value of this parameter must be of half size of "Filter
window" or smaller.
Whether the BTS reports the frame erase ratio in a measurement report or preprocessed measurement report
If the FER carried in the measurement report (MR) received is lower than or equal to "FER threshold 1", the value of
"FER 0 and Quality Level N" is incremented by one. If the FER in the MR received is greater than "FER threshold 1"
If the FER carried in the MR received is greater than "FER threshold 2" but meanwhile lower than "FER threshold 3",
the value of "FER 2 and Quality Level N" is incremented by one.
If the FER carried in the MR received is greater than "FER threshold 3" but meanwhile lower than "FER threshold 4",
the value of "FER 3 and Quality Level N" is incremented by one.
If the FER carried in the MR received is greater than "FER threshold 4" but meanwhile lower than "FER threshold 5",
the value of "FER 4 and Quality Level N" is incremented by one.
If the FER carried in the MR received is greater than "FER threshold 5" but meanwhile lower than "FER threshold 6",
the value of "FER 5 and Quality Level N" is incremented by one.
If the FER carried in the MR received is greater than "FER threshold 6" but meanwhile lower than "FER threshold 7",
the value of "FER 6 and Quality Level N" is incremented by one.
If the FER carried in the MR received is greater than "FER threshold 7", the value of "FER 7 and Quality Level N" is
incremented by one.
This parameter specifies the frequency hopping mode of a cell. When this parameter is set to "NO_FH", all the TRXs
of the cell do not join in frequency hopping. When this parameter is set to "BaseBand_FH", the cell is in baseband
The name of the file cannot contain the path and suffix. The suffix is automatically added. The name of the file is
composed of English letters, numerals, and common symbols, and the characters (@, #, !, %, ^, &, *, [, ], /, \, ', and ")
Path of the target file
Name of the backup file. The file name is composed of English letters, numerals, and common symbols, and the
characters (@, #, !, %, ^, &, *, [, ], /, \, ', and ") cannot appear in the file name.
Path to save the exported file. The path must be a valid path on the OMU server. If the OMU runs the LINUX system,
the input path must start with the symbol "/" or "\", for example, "/mml". If the OMU runs the WINDOWS system, the
Type of the alarm log file to be exported
Maximum number of former values when the receive level of the serving cell or the receive level of the neighbor cell
is filtered. The greater the value, the greater the weight of the former receive levels; otherwise, the greater the weight
Execution result.
If you select "FALSE", only the records of failed operations are displayed. If you select "TRUE", only the records of
Whether to enable 0.2 dB downlink power control. This power control function improves the power control precision.
Whether to start the fire-extinguishing equipment of the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
This parameter specifies the static Abis resource load threshold. If the static Abis resource load is less than the static
Abis resource load threshold, the TCHF is preferentially allocated. Otherwise, whether the TCHF or the TCHH should
Time threshold for delaying the report of a clear alarm. If the alarm recurs within the time specified by this parameter
after it is cleared, the clear alarm is not reported. Otherwise, the clear alarm is reported. If this parameter is set to 0,
Time threshold for delaying the report of an alarm. If the alarm is cleared within the time specified by this parameter,
the alarm is not reported. Otherwise, the alarm is reported. If this parameter is set to 0, the alarm is reported
Whether to enable the filtering of the intermittent alarms. If the value of this parameter is "DISABLE", "Flash Statis
Alarm Raise Time Window" and "Flash Statis Alarm Clear Time" are invalid.
Time window for observing the clearance of the intermittent alarms. In this time window, the BTS statistical alarm is
cleared if the occurrence of the intermittent alarm meets the related threshold.
Time window for observing the intermittent alarms generated during the statistical period. In this time window, the
BTS statistical alarm is reported if the occurrence of the intermittent alarm meets the related threshold.
Service timeslot assignment mode for the BTS. If this parameter is set to FIX_16K_ABIS, the BSC6900 assigns a
fixed Abis transmission timeslot to a TCH. If this parameter is set to FLEX_ABIS, the BSC6900 assigns an Abis
Whether to enable the function of Flex mobile allocation index offset (MAIO). In the tight frequency reuse case of the
GSM system, adjacent-channel interference and co-channel interference easily occur between channels. If the
Whether to enable the function of the Flex training sequence code (TSC). If the value of this parameter is ON and
the BTS supports the Flex TSC function, the BSS dynamically allocates TSCs to hopping frequencies for improving
Period of collecting the traffic statistics
Fast flux measurement period. The ratio of the uplink flux to the downlink flux is calculated at the interval specified by
this parameter to determine the current service priority type.
Port flow control switch
Link flow control switch
Link flow control switch
Logical port flow control switch
Port flow control switch
Specified port flow control switch
One of the nine parameters (filter parameters A1 to A8 and filter parameter B) used to configure the filter for
determining whether the received signal level drops rapidly. The computation formula is as follows:
One of the nine parameters (filter parameters A1 to A8 and filter parameter B) used to configure the filter for
determining whether the received signal level drops rapidly. The computation formula is as follows:
One of the nine parameters (filter parameters A1 to A8 and filter parameter B) used to configure the filter for
determining whether the received signal level drops rapidly. The computation formula is as follows:
One of the nine parameters (filter parameters A1 to A8 and filter parameter B) used to configure the filter for
determining whether the received signal level drops rapidly. The computation formula is as follows:
One of the nine parameters (filter parameters A1 to A8 and filter parameter B) used to configure the filter for
determining whether the received signal level drops rapidly. The computation formula is as follows:
One of the nine parameters (filter parameters A1 to A8 and filter parameter B) used to configure the filter for
determining whether the received signal level drops rapidly. The computation formula is as follows:
One of the nine parameters (filter parameters A1 to A8 and filter parameter B) used to configure the filter for
determining whether the received signal level drops rapidly. The computation formula is as follows:
One of the nine parameters (filter parameters A1 to A8 and filter parameter B) used to configure the filter for
determining whether the received signal level drops rapidly. The computation formula is as follows:
Trend of the received signal level of the cell during a period. This parameter helps to configure the filter for
determining whether the received signal level drops rapidly. If this parameter is higher, a more rapid signal level drop
This parameter determines whether the BSC transfers the LLC PDUs in the buffer to the target cell or discards these
LLC PDUs in the buffer when receiving the FLUSH-LL message from the SGSN.
Maximum transmit power level of MSs. As one of the cell reselection parameters in system message 3, this
parameter is used to control the transmit power of MSs. For details, see GSM Rec. 05.05.
Type of the FMUA board
Name of the electronic label file
Name of the file
Name of the file
Name of the file. The following special characters are not allowed in the file name: \, /, :, *, ?, ", <, >, |, (, ), &, and $.
Name of the specified file. By default, the file is in the OMU active-area path \ftp\license folder.
File name of the software to be downloaded
File name of the software to be downloaded.The file name must be with the extension of *.zip.If you do not enter the
file name, all the valid files in the directory are downloaded. These valid files are extracted from the patch package.
Switch specifying whether to allow the downlink EGPRS TBF and the uplink GPRS TBF to share the same channel.
On: allow the downlink EGPRS TBF and the uplink GPRS TBF to share the same channel; Off: prohibit the downlink
Length of the timer for determining the intermittent disconnection of the SS7 link to the DPC. When the time of SS7
link disconnection exceeds the period specified by the timer, the BSC performs corresponding operations, including
Time limit for restraining the noise level
Whether the forced phase-2 access is allowed for the MSs
Whether to forcibly enable the EFR function. When this parameter is set to YES, if both the MS and the BSC6900
support the enhanced full rate (EFR), the BSC6900 forcibly enables the EFR function even if the MSC does not
Whether an MS is forced to send a Handover Access message, which is indicated by an information element in the
handover command.
Port No. of the father BTS connected with the BTS
Number of the port for the destination father BTS
Maximum time of delay for multiplexing. This parameter is used for the system to send the multiplexed data. If the
time for buffering the data exceeds this value, the system does not wait for the multiplexing of other packets. In this
Whether to generate the frequency and BSIC by using the automatic optimization algorithm
If this switch is on, it indicates that the frequency and BSIC are generated automatically. If this switch is off, it
indicates that the data must be configured manually.
If this switch is on, it indicates that the frequency and BSIC are generated automatically. If this switch is off, it
indicates that the data must be configured manually.
MP segment size,the length of packet should be bigger or equel with it.
Frame offset of the BTS clock
Frame offset. The frame offset technology arranges the frame numbers of different cells under the same BTS to be
different from one another by one frame offset. Thus, the FCH and SCH signals of neighboring cells do not appear in
Whether the downlink discontinuous transmission (DTX) function is enabled for full rate (FR) calls. This function is
also restricted by the DTX switch in the MSC. If the MSC allows the downlink DTX for calls and the value of this
Time mode used when the log is exported. "ONTIME" indicates the time between two exact time. "RELATIVE_T"
indicates the time before the current time.
Based on different requirements, you can set different time points for the scheduled task.
Seven time modes are available:
Frequency of the TRX
Frequency 1
Frequency 10
Frequency 11
Frequency 12
Frequency 13
Frequency 14
Frequency 15
Frequency 16
Frequency 17
Frequency 18
Frequency 19
Frequency 2
Frequency 20
Frequency 21
Frequency 22
Frequency 23
Frequency 24
Frequency 25
Frequency 26
Frequency 27
Frequency 28
Frequency 29
Frequency 3
Frequency 30
Frequency 31
Frequency 32
Frequency 33
Frequency 34
Frequency 35
Frequency 36
Frequency 37
Frequency 38
Frequency 39
Frequency 4
Frequency 40
Frequency 41
Frequency 42
Frequency 43
Frequency 44
Frequency 45
Frequency 46
Frequency 47
Frequency 48
Frequency 49
Frequency 5
Frequency 50
Frequency 51
Frequency 52
Frequency 53
Frequency 54
Frequency 55
Frequency 56
Frequency 57
Frequency 58
Frequency 59
Frequency 6
Frequency 60
Frequency 61
Frequency 62
Frequency 63
Frequency 64
Frequency 7
Frequency 8
Frequency 9
Whether to enable the automatic frequency correction algorithm. This parameter is used for the fast-moving
handover algorithm. If the parameter is set to YES, the BTS calculates the speed at which an MS leaves or
Frequency correction parameter. Used for the fast-moving handover algorithm, the value of this parameter must be
translated into a binary number. The value consists of 16 bit. The most significant bit indicates whether the parameter
Frequency band types of the board This parameter is only applicable to the
DDPU/DFCU/DFCB/DCOM/DDPM/DCBM.
Threshold for load sharing in the 900 MHz frequency band. Assume that an MS supports multiple sub-bands in the
900 MHz frequency band. If the cell load is equal to or less than this threshold, the BSC does not consider the priority
List of frequency bands
Frequency multiplexing mode in the TRX. To enable a loose frequency multiplexing mode such as 4x3 multiplexing,
set this parameter to LOOSE. To enable a tight frequency multiplexing mode such as 1x3 or 1x1, set this parameter
List of the frequencies to be measured. This parameter is represented as a character string where the IDs of the
TRXs to be measured are separated by &, such as 1&124&956.
Type of a scanning result in the period from the start of a frequency scanning task to the reporting of the scanning
result.
Whether to enable the edge handover algorithm. When an MS makes a call at the edge of a cell, the call may drop if
the received signal level is too low. To avoid such a call drop, the edge handover algorithm is involved. When the
Whether the uplink DTX function is enabled for FR calls. For details, see GSM Rec. 05.08. Uplink DTX is not
restricted by the MSC. If this parameter is set to May_Use, the MS can use DTX. If this parameter is set to Shall_Use
Slot No. of the father BTS
Slot No. for the port of the father BTS
Subrack No. of the father BTS
Subrack No. for the port of the father BTS
Type of the file used for saving exported logs
Activation factor table index
Activation factor table index
Activation factor table index
ATCB difference between the overlaid and underlaid subcells
Duration of the handover from full rate to half rate. If the cell load is greater than the preset threshold, the calls that
meet the conditions for the handover from full rate to half rate are handed over from full rate to half rate in this
According to the P/N rule, if the conditions for the handover from full rate to half rate are met for P seconds within N
seconds, the handover is triggered.
Path loss difference between the overlaid and underlaid subcells
Period of the handover from full rate to half rate. If the cell load is greater than the preset threshold, the calls that
meet the conditions for the handover from full rate to half rate are handed over in "H-F Ho Duration". This parameter
According to the P/N rule, if the conditions for the handover from full rate to half rate are met for P seconds within N
seconds, the handover is triggered.
If the available forward bandwidth is less than or equal to this value, the forward congestion alarm is emitted and
forward congestion control is striggered.
If the available forward bandwidth is greater than this value, the forward congestion alarm is cleared and forward
congestion control is stopped.
If the ratio of available forward bandwidth is greater than this value, the forward congestion alarm is cleared and
forward congestion control is stopped.
If the ratio of available forward bandwidth is less than or equal to this value, the forward congestion alarm is emitted
and forward congestion control is triggered.
If the available forward bandwidth is greater than this value, the forward overload congestion alarm is cleared and
forward overload control is stopped.
If the ratio of available forward bandwidth is greater than this value, the forward overload congestion alarm is cleared
and forward overload control is stopped.
If the available forward bandwidth is less than or equal to this value, the forward overload congestion alarm is emitted
and forward overload control is triggered.
If the ratio of available forward bandwidth is less than or equal to this value, the forward overload congestion alarm is
emitted and forward overload control is triggered.
Ratio of reserved forward bandwidth for handover user
Reserved forward bandwidth for handover user
If the load balance between a 2G cell and a 3G cell is greater than the threshold, load balance is triggered.
Coefficient used to modulate the load level of a 2G system so that the load level of the 2G system can be compared
with that of a 3G system.
G711 Mode. A/U law configuration, 0-A law (default), 1-U law
Expected signal receiving strength on the BTS side when GPRS dynamic power control is implemented
End time for collecting the offset information
Cell load threshold for collecting the offset information. If the load threshold is exceeded, the offset information is not
collected.
Whether to collect the offset information
Start time for collecting the offset information
Obtains the QoS parameter from the Aggregate BSS QoS Profile (ABQP) of packet flow context (PFC) when the MS
and the network support the PFC; obtains the QoS parameter from the uplink request originated by the MS or the DL
This parameter specifies whether to enable the VGCS/VBS check function. If the BSS works abnormally, the BTS
may periodically send notification messages even if VGCS/VBS is over. In this case, an MS responds continuously
Format of the geographic coordinates. The values include "DEG" and "SEC".
Whether the assignment of channels in overlaid subcells is enabled for the VGCS service in the case of underlaid
subcell congestion. Generally, only the channels in underlaid subcells can be assigned to the VGCS service.
Whether direct preemption of the channels of other services is enabled for the VGCS service. If the value of this
parameter is NO, a handover is performed for the call whose channel is preempted. If the value is YES, calls on the
Global routing management switch. If this switch is turned on, the IP addresses in the controlled range cannot be in
the same network segment.
Delay of transmit diversity when GMSK is used. Generally, the parameter is applicable to general fading
environments. In this case, the transmit diversity can obtain the gain of 3 dB to 5 dB. The fading degrees, however,
Whether the current cell supports GPRS
Whether the currently cell supports the GPRS
Hysteresis value of the cell in the same routing area. When the MS in the ready state reselects a cell, if the original
cell and the target cell are in the same routing area, the C2 values of the two cells at the border of the cell are quite
EGPRS priority type of the channel
If this parameter is set to GPRS, the EDGE MSs cannot use this channel.
Threshold of hierarchical cell structure (HCS) signal strength. The MS calculates the C31 according to the signal
strength and its threshold and selects the adjacent cell during cell reselection.
Timer used when the MS calculates the C2 (used to evaluate the channel quality during cell reselection). The time
information is transmitted in the system message of each cell.
Used for the GPRS transmission quality statistics. When the transmission quality threshold is exceeded, the
transmission quality is regarded deteriorated.
This parameter is used to prevent repeated cell reselection of a fast moving MS. The MS does not select this cell
when the duration of maintaining the BCCH signal channel strength does not reach the penalty time.
Synchronization clock adopted when two satellite cards are used together. GPS:Trace GPS only. GLONASS:Trace
GLONASS only. GPSGlonass:Trace GPS and GLONASS.
Period for reporting GPS data
Whether to allow hierarchical access and to reserve resources for high-priority MSs
Number of the VGCS call that the BTS originates in the timeslot in the TRX in fallback mode. This parameter is
represented in decimal, such as 10000569. If this parameter is set to 100000000, the channel is not configured with
Number of the VGCS call that the BTS originates in the timeslot in the TRX in fallback mode. This parameter is
represented in decimal, such as 10000569. If this parameter is set to 100000000, the channel is not configured with
Index of the BSC Node Redundancy Group. It identifies a BSC redundancy group. The BSC node redundancy is a
function through which two BSCs form a redundancy group. The two BSCs in a redundancy group work in 1+1 load
Name of the BSC Node Redundancy Group
Maximum number of secondary links that are released in batches when the Abis resource preemption occurs on the
Abis interface
Transport resource group number
Type of the transport resource group
Geographical coverage of a simple cell broadcast message. You can run "DSP GSMSCB" to query and obtain the
information.
Ratio of bandwidth occupied by the CS service in the GSM
Standard priority for GSM CS(Circuit Switched) high-priprity MSs. 15 is the highest priority.
Number of neighboring cells that meet the following conditions: If "MBR" is indicated in a system message, the MS
reports the number of neighboring cells at each frequency band. If the MS reports the number of neighboring cells at
Whether to support the cell reselection from the GSM network to the TD network in the packet transmission mode
Packet type against the ICMP attack
When the BTS is accessed from the public network, the BTS security network IP address must be configured.
IP address of the BTS security gateway. This parameter needs to be configured when the BTS connects to the
BSC6900 through the public network.
Whether to support CS half rate data services
ATCB difference between the overlaid and underlaid subcells
Duration of the handover from half rate to full rate. If the cell load is less than the preset threshold, the calls that meet
the conditions for the handover from half rate to full rate are handed over from half rate to full rate in this duration.
According to the P/N rule, if the conditions for the handover from half rate to full rate are met for P seconds within N
seconds, the handover is triggered.
Path loss difference between the overlaid and underlaid subcells
According to the P/N rule, if the conditions for the handover from half rate to full rate are met for P seconds within N
seconds, the handover is triggered.
Whether the tower-top amplifier is installed on antenna tributary 1.
Whether the tower-top amplifier is installed on antenna tributary 2.
Heartbeat interval when the SCTP server is idle
Number of the cabinet where the main board of the RXU chain or ring is located.
According to the P/N rule, if the conditions for the handover to a different micro cell due to fast movement are met in
P of N measurement reports, the handover is triggered.
According to the P/N rule, if the conditions for the handover to a different micro cell due to fast movement are met in
P of N measurement reports, the handover is triggered.
Threshold for interrupting the power supply to the TRXs. If the BTS works with the battery power supply, when the
battery voltage is less than this threshold, the BTS interrupts the power supply to the TRXs to protect the lower-level
Threshold for interrupting the power supply to the TMU. If the BTS works with the battery power supply, when the
battery voltage is less than this threshold, the BTS interrupts the power supply to the TMU.
Type of a high frequency type supported by the BSC6900,
Frequencies on DCS1800: 512-885
Full rate TCHs are assigned preferentially to the MSs with priority levels equal to or less than this threshold, except
when the MSs request only half or full rate TCHs.
This parameter specifies whether the MS with priority level 1 directly releases the preempted call. When this
parameter is set to Yes, the access delay of MSs with high priorities is ensured and the access rate of MSs with high
Whether to enable the priority-based channel assignment algorithm
Whether to enable load power-off against high temperature
Whether to consider history priority records during channel assignment.
If this parameter is set to YES, the history priority records are considered. If this parameter is set to NO, the history
Maximum History Password Numbers.
Whether the cell supports the MS with the DTM multi-timeslot capability
Whether to assign a channel in the overlaid or underlaid subcell in the case of the intra-BSC incoming handover to
the concentric cell.
Whether to allow handover between different operators. If the BSC6900 supports RAN sharing, MSs in a cell of this
operator can be handed over to a cell of other operators, or vice versa.
If the downlink received signal level of a neighbor cell is greater than "Min DL Level on Candidate Cell" plus "Min
Access Level Offset", the neighbor cell can be listed in the candidate cell queue for handover.
If the uplink received signal level of a neighbor cell is greater than "Min UL Level on Candidate Cell" plus "Min
Access Level Offset", the neighbor cell can be listed in the candidate cell queue for handover.
Type of indexing the target cell
Unique name of the target cell
Whether to use handover algorithm generation 1 or 2 currently
Handover direction forcast switch. When this parameter is set to YES, the BSC6900 can forecast the handover
direction of the call in fast handover so that the best target cell can be selected for handover.
This parameter indicates P in the P/N rule for MS handover direction forcast.
P/N rule: Among N handovers, the MS is handed over to Class B chain neighboring cell for successively P times,
This parameter indicates N in the P/N rule for MS handover direction forcast.
P/N rule: Among N handovers, the MS is handed over to Class B chain neighboring cell for successively P times,
Fast handover can be triggered only when the downlink level of the serving cell is less than this parameter.
According to the P/N rule, if the conditions for the handover to a better 3G cell are met for P seconds within N
seconds, the handover is triggered.
According to the P/N rule, if the conditions for the handover to a better 3G cell are met for P seconds within N
seconds, the handover is triggered.
The 3G better cell handover can be triggered only when the Ec/No of a neighboring 3G cell is greater than this
threshold for a period of time.
According to the P/N rule, if the conditions for fast handover are met in P of N measurement reports, the handover is
triggered.
Type of handover in terms of connection transfer between channels or between cells
Fast handover can be triggered only when the path loss difference between the serving cell and a neighbor cell on
the chain is equal to or greater than this parameter.
If the cell is an enhanced concentric cell, this parameter with the current downlink received signal level and "UtoO
HO Received Level Threshold" determines whether to assign a channel in the underlaid subcell to the intra-BSC
This parameter specifies whether a 2G cell or to a 3G cell is preferentially selected as the target cell for handover.
When this parameter is set to Pre_2G_Cell, the BSC preferentially selects a 2G candidate cell as the target cell for
An MS cannot be handed over from the underlaid subcell to the overlaid subcell in this duration after the MS is
handed over from the overlaid subcell to the underlaid subcell successfully.
Index of the frequency hopping data, used for a TRX to locate the frequency hopping sequence
Logical number of the MA group
Implementation mode of frequency hopping
Whether to enable power boost before handover.
When the receive level of an MS drops rapidly, a handover occurs. In this case, the BSC6900 cannot adjust the
If the receive level of the neighboring 2G cell that ranks the first in the candidate cell list is equal to or smaller than
this threshold, the BSC preferentially selects a neighboring 3G cell as the handover target cell. Otherwise, the BSC
If this parameter is set to ON, the channel on a single frequency of an MA group is allocated to an MS with the non-
FH attribute.
Hoping sequence number (HSN) of a hopping antenna group. If the value of this parameter is 0, the services over a
TRX are adjusted to other TRXs in the hopping antenna group in sequence. If this parameter is set to a value from 1
TRX index that a hopping antenna index corresponds to. A hopping antenna enables signals of multiple TRXs to
switch between several antennas instead of fixing an antenna for a TRX. This reduces the effect of Rayleigh fading
Frequency hopping mode of the TRX. Frequency hopping assists in interference averaging and frequency diversity.
If this parameter is set to RF_FH, the TX and RX parts of the TRX take part in the frequency hopping. In this case,
To avoid ping-pong handover, the received signal of the original serving cell is decreased by "Quick handover punish
value" in "Quick handover punish time" after fast handover succeeds.
Time for reserving the handover reference for one of the two BSCs that collect the offset information
The 3G better cell handover is triggered only when the RSCP of a neighboring 3G cell is greater than this threshold
for a period of time.
Whether an HO REQ ACK message contains the information element Speech Version during an SDCCH handover.
If a signaling channel handover between BSCs fails, the value of this parameter may need to be adjusted.
According to the P/N rule, if the conditions for the handover to a better 3G cell are met in P of N measurement
reports, the handover is triggered.
According to the P/N rule, if the conditions for the handover to a better 3G cell are met in P of N measurement
reports, the handover is triggered.
According to the P/N rule, if the conditions for fast handover are met in P of N measurement reports, the handover is
triggered.
Indicates the host type of the signalling point.
When the BSC node redundancy feature is enabled, the primary BSC and the secondary BSC each must be
Host type of an IP BTS
Handover threshold during the handovers between cells on different layers or of different priorities. This value is used
to suppress inter-layer ping-pong handovers.
Fast handover can be triggered only when the uplink signal level of the serving cell is less than this parameter.
Whether to enable the TRX to support antenna hopping
In a GSM cell, the BCCH broadcasts the frequency, frame number, system information, and paging group. If an MS
Whether to enable the TRX to support antenna hopping
In a GSM cell, the BCCH broadcasts the frequency, frame number, system information, and paging group. If an MS
The number of the optical port of the main board in the RXU chain or ring.
Maximum priority level of an MS that can use reserved channel resources. If the priority level of an MS is greater
than this parameter, the MS is considered a low-priority MS. If the priority of an MS is equal to or less than this
Whether to enable the configuration of power system parameters.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Load power-off voltage threshold.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
This parameter determines whether the BSC6900 supports new establishment causes of an MS in the initial access
request. This parameter does not affect the half-rate function of cells.
Whether the downlink DTX function is enabled for half rate (HR) calls. This function is also restricted by the DTX
switch in the MSC. If the MSC allows the downlink DTX for calls and the value of this parameter(HRDLDTX) is YES,
Whether to enable the BSC to assign half or full rate channels to MSs according to the channel seizure ratio in the
overlaid and underlaid subcells
Whether the uplink DTX function is enabled for HR calls. For details, see GSM Rec. 05.08. Uplink DTX is not
restricted by the MSC. If this parameter is set to May_Use, the MS can use DTX. If this parameter is set to Shall_Use
Hopping sequence number (HSN), indicating 64 types of frequency hopping sequences. If this parameter is set to 0,
the frequency hopping is performed in sequence.
Number of the slot where the main board of the RXU chain or ring is located. The slot No. is unique in the same BTS.
Whether dynamic use of HSNs is enabled. If the functions of frequency hopping and Flex MAIO are enabled in a cell
and the value of this parameter is ON, adjacent-channel interference between channels can be reduced.
Number of the subrack where the main board of the RXU chain or ring is located. The subrack No. is unique in the
same BTS.
Bidirectional Forwarding Detection Hop Type.
If the ambient temperature is higher than "High Temperature Critical Point", the temperature control system controls
the difference between the inlet and outlet temperatures.
If the outlet temperature is higher than "High Temperature Critical Point" and the difference between the outlet
temperature and ambient temperature reaches the value of this parameter, the temperature control system controls
Whether to enable battery power-off against high temperature.
Humidity alarm switch
Upper limit of humidity. When the humidity exceeds the upper limit, a humidity alarm is reported.
Lower limit of humidity. When the humidity is lower than the lower limit, a humidity alarm is reported.
When the ambient humidity of the APMU is greater than the value of this parameter, the BTS reports an overhigh
ambient humidity alarm.
When the ambient humidity is greater than the value of this parameter, the BTS reports an overhigh ambient
humidity alarm.
When the ambient humidity of the APMU is less than the value of this parameter, the BTS reports an overlow
ambient humidity alarm.
When the ambient humidity is less than the value of this parameter, the BTS reports an overlow ambient humidity
alarm.
Delay for which the BTS waits to switch on the air conditioner
This timer is started after a connection is established successfully. If a detection message is not received when this
timer expires, the connection will be released.
Duration in IASU mode
Port number in IASU mode. For the BTS3002C, the port number cannot be set to "E1PORT3".
Type of the transmission board in IASU mode
This timer is started after a connection is established successfully. When this timer expires, a detection message will
be sent to the peer end.
Minimum C/I ratio that IBCA AMR FR services allow. An idle channel can be assigned to such a service only when
the C/I ratio of the idle channel is greater than this threshold. In addition, a new call associated with such a service
Minimum C/I ratio that IBCA AMR HR services allow. An idle channel can be assigned to such a service only when
the C/I ratio of the idle channel is greater than this threshold. In addition, a new call associated with such a service
Whether to enable the IBCA algorithm
Length of the timer for a new call to wait for the measurement report (MR) on the signaling channel when dynamic
measurement of the BA2 list is enabled during assignment. If this parameter is set to 0, dynamic measurement of the
Number of measurement reports sampled for averaging path loss. A single measurement report may not reflect the
actual network situations accurately. Therefore, the BSC needs to average the measured values in several
When the IBCA algorithm is enabled, this parameter is used to calculate the actual soft blocking threshold of an
existing call. The formula is as follows: Actual soft blocking threshold of an existing call = Configured soft blocking
When the IBCA algorithm is enabled, this parameter is used to calculate the target CIR of an existing call. The
formula is as follows: Target CIR of an existing call = Target CIR in use + Target CIR Offset of IBCA Set-Up Call.
Difference between uplink and downlink path losses, which is used to estimate the downlink path loss of a call when
the downlink path loss cannot be computed directly according to a measurement report. This parameter is configured
Whether to measure the IBCA neighbor cells of the serving cell dynamically. If the dynamic measurement is enabled,
when a call uses a channel, the BSC sends the SACCH Modify message to modify the frequencies in the BA2 table
Length of the timer for a call to measure the path loss in the neighboring cell with strong interference of the target
cell. The call to be handed over needs to measure the path loss before initiating the handover to the target cell when
Whether the IBCA flexible TSC function is enabled. When this parameter is set to NO, the flexible TSC function is
disabled and the configured TSC is used. When the BTS supports Flex TSC and this parameter is set to YES, the
Whether the IBCA forced BTS synchronization is allowed. When this parameter is set to YES, the synchronization
procedure is performed even though the BTSs are insynchronous. When this parameter is set to NO, the existing
Minimum C/I ratio that IBCA FR/EFR services allow. An idle channel can be assigned to such a service only when
the C/I ratio of the idle channel is greater than this threshold. In addition, a new call associated with such a service
Length of the timer for a call to wait for other valid MRs after receiving the first valid MR of the target cell if dynamic
measurement of the BA2 list is enabled during handover. When this parameter is set to 0, the call does not wait for
Minimum C/I ratio that IBCA HR services allow. An idle channel can be assigned to such a service only when the C/I
ratio of the idle channel is greater than this threshold. In addition, a new call associated with such a service can be
In the ICDM matrix algorithm, the signal strength (0-63) is divided into 10 levels. The signal strength that is smaller
than or equal to the value of this parameter is at the initial level.
Whether to enable the ICDM algorithm for the cell. The ICDM algorithm helps to improve the precision in estimating
the path loss of an IBCA neighbor cell and to increase the efficiency of the IBCA algorithm.
Period of information exchange between the BSC boards. The information helps to estimate the C/I ratio for the IBCA
algorithm.
Adds a specified offset to the downlink target receive level when power control algorithm III is used to calculate the
initial transmit power of a BTS in the IBCA function
Adds a specified offset to the uplink target receive level when power control algorithm III is used to calculate the
initial transmit power of an MS in the IBCA function
Adds a specified offset to the downlink target receive quality when power control algorithm III is used to calculate the
initial transmit power of a BTS in the IBCA function
Adds a specified offset to the uplink target receive quality when power control algorithm III is used to calculate the
initial transmit power of an MS in the IBCA function
In an IUO cell (or a CoBCCH cell), the path loss of an MS to the serving cell or a neighboring cell measured on the
underlay is used together with this parameter to estimate the path loss on the overlay. IUO path loss compensation =
Determines the MAIO selection method for each timeslot. The Optimal MAIO policy selects the optimal MAIO being
evaluated, while the Random MAIO policy randomly selects a MAIO out of qualified MAIOs.
The IBCA interference evaluation process only considers the interference of the strongest N existing calls on the
newly-established call being evaluated. This parameter corresponds to the above-mentioned N.
Indicates whether this neighboring cell is the IBCA neighboring cell of the serving cell. That is, when a cell is
configured as the neighboring cell of the serving cell, whether the IBCA algorithm considers the interference between
Estimates the receive level of the unmeasured IBCA neighboring cells. When a consecutive "IBCA Non
Measurement Ncell Stat. Num" measurement reports cover less than six neighboring cells (or the number of the
When the IBCA algorithm is enabled, this parameter is used to calculate the target CIR of a new call. The formula is
as follows: Target CIR of a new call = Target CIR in use + Target CIR Offset of IBCA New Call
Length of the timer for a call to measure the path loss in the neighboring cell with strong interference of the target
cell. The call to be handed over needs to measure the path loss before initiating the handover to the target cell when
Estimates the receive level of the unmeasured IBCA neighboring cells. When a consecutive "IBCA Non
Measurement Ncell Stat. Num" measurement reports cover less than six neighboring cells (or the number of the
When the IBCA algorithm is enabled and the HSN is not 0, the IBCA priority and the SDCCH/PDCH priority are
divided by this corrected factor respectively to reduce the weight of IBCA priority. In addition, the priority of the
Specifies a period during which the inter-BSC information exchange must be completed. The information is mainly
used by IBCA for C/I ratio estimation.
When the path loss of an MS to a neighboring cell cannot be measured based on the existing measurement results,
it is estimated based on the path loss of the MS to the serving cell plus the IBCA path loss offset.
Considers the influence of history path loss information during the calculation of the ICDM algorithm path loss. The
smaller the filtering coefficient, the smaller the influence of history path loss; on the other hand, the larger the filtering
Estimates the receive level of the unmeasured IBCA neighboring cells. When a consecutive "IBCA Non
Measurement Ncell Stat. Num" measurement reports cover less than six neighboring cells (or the number of the
Use this parameter when the path loss of an MS to serving cells cannot be measured based on the existing
measurement results
MSs that support SAIC can tolerate a lower carrier-to-interference ratio. This variable indicates the downward
adjustment step of the soft blocking threshold of SAIC MSs.
Whether to deny the access of a call when none of the MAIO evaluation results meets the C/I ratio requirement of
the call during channel assignment
Whether the handover of the calls on the single channels is allowed (single channels are the two half-rate sub-
channels on a timeslot, in which only one is in the occupied state) when single channels are to be adjusted to a full-
Whether a MAIO meets the access requirement. When the C/I ratio of a MAIO is higher than this threshold, the
MAIO can be assigned to the call being processed.
Whether to enable the IBCA algorithm for the overlay and underlay of an IUO cell
Whether a single IBCA MS can dynamically measure the neighboring cells. When this parameter is set to YES, the
neighboring cells where "IBCA Dynamic Measure Neighbor Cell Flag" is set to YES are dynamically measured.
The lowest C/I ratio that can be tolerated by IBCA WAMR FR. The C/I ratio of an idle channel must be larger than
this parameter. Otherwise, it cannot be assigned. In addition, the system does not allow a newly-established call
This parameter is used to enable the Intelligent Combiner Bypass (ICB) function on the BCCH TRX of a cell.
This parameter specifies whether to allow the cell to enable the ICB function. When this parameter is set to YES, the
Whether to enable the intelligent control of the diesel engine. If this parameter is set to ENABLE, the PMU will control
the diesel engine automatically according to the settings of the parameters to save the energy. This parameter is set
ICMP packet length. It is the total length of the ICMP packet containing the IP header.
DSCP corresponding to the interaction service with the THP level of PRIORITY1
DSCP corresponding to the interaction service with the THP level of PRIORITY2
DSCP corresponding to the interaction service with the THP level of PRIORITY3
Number of the scheduled task
Number of the scheduled task
Index
This parameter indicates the idle code of the A interface. It is used for the interconnection of the A interfaces.
IDLE code
When the number of idle SDCCH channels in a cell is smaller than this parameter, the system searches for available
TCHs and transforms them into SDCCH channels.
Index type
BTS index type
Type of an index
Index type
Type of an index
Subscribers can specify the cell according to the index or the name.
Index type of the BTS. BYNAME: query by BTS name; BYID: query by BTS index.
Index type. BYNAME: query by name; BYID: query by index.
Index of the semipermanent link
Support the index based on the TLLI and IMSI mode
Index type, supporting the index based on the cell and BSC mode.
Whether the handshake mechanism is enabled at the Cb interface. Currently, the BSC6900 and the CBC
communications through the TCP/IP protocol. Thus, the BSC6900 may not detect communication link disconnection
Number of the outgoing interface of a link
Whether to set the middle frequency offset to positive offset or minus offset
Indication offset in the middle frequency offset configuration
Whether to report the progress. "NO" indicates that the progress is not reported. "YES" indicates that the progress is
reported.
Number of invalid measurement reports allowed when the BSC6900 filters the measurement reports. When the
number of received measurement reports is no larger than this parameter, the BSC does not perform filtering or
Value of an IMEI
Timer for the BSC6900 waiting for a CC message after sending a CR message. If the timer expires, the seized
SDCCH is released.
The channel activation and immediate assignment messages are sent at the same time to accelerate the signaling
processing, thus increasing the response speed of the network.
This parameter specifies whether to support the takeover of the packet immediate assignment by the BTS. It is
relative to the uplink immediate assignment. To improve the access rate of the MS, the BSS allocates the uplink TBF
Whether to allow immediate TCH assignment. If this parameter is set to YES, the BSC can assign a TCH
immediately when there is no available SDCCH for a channel request. If this parameter is set to NO, the BSC can
Maximum time delay in resending an immediate assignment message. Within the period specified by this parameter,
an immediate assignment message can be dispatched and retransmitted. Otherwise, the message is not dispatched
Maximum number of retransmissions of an immediate assignment message. When the value of this parameter is
reached, the immediate assignment message is not retransmitted even if the value of "Max Delay of Imm_Ass
Whether the BSC6900 sends immediate assignment retransmission parameters to the BTS
Whether to assign channels according to the access_delay value in channel request messages during immediate
channel assignment
When the access_delay value in the channel request message is smaller than this parameter, the overlay channels
are assigned preferentially; otherwise, the underlay channels are assigned preferentially.
Whether to adjust the offset time immediately after the BTS is reset
Timer carried by the Wait Indication information element when the BSC6900 sends an immediate assignment reject
message to an MS.
Value of an IMSI
International mobile subscriber identity of the MS. IMSI containing the number 0 to 9.
Timer for the BSC6900 waiting for a handover complete message after sending a handover request acknowledgment
message in 2G/3G handover or inter-BSC handover. If the timer expires, a Clear REQ message is reported.
Threshold for fine tuning the BTS clock. If the offset of the BTS clock is smaller than the threshold, no fine tuning is
performed.
Fine tuning period in the BSC
Included angle formed by the major lobe azimuths of the antennas in two cells under one BTS. A major lobe azimuth
is measured from the due north to the direction of the cell antenna in a clockwise rotation.
Number of the in-port cabinet on a BTS
Whether to separate E1 from other optical fibers for the use of other devices. If this parameter is set to YES, other
BTSs can connect to the BSC6900 through the independent E1 port 3 of the BTS3006C/BTS3002E.
The triggering of intra-cell F-H handovers must meet the P/N criteria, that is, when the condition for intra-cell F-H
handovers is met for P seconds during N seconds, an intra-cell F-H handover is triggered. This parameter
The triggering of intra-cell F-H handovers must meet the P/N criteria, that is, when the condition for intra-cell F-H
handovers is met for P seconds during N seconds, an intra-cell F-H handover is triggered. This parameter
Information exchange content to be supported
Infrared alarm switch
For an AMR call, if the currently occupied channel is a full rate channel and the Radio Quality Indication (RQI) is
always higher than the threshold set by this parameter, an intra-cell F-H handover is triggered.
For an AMR call, if the currently occupied channel is a half rate channel and the Radio Quality Indication (RQI) is
always lower than the threshold set by this parameter, an intra-cell H-F handover is triggered.
Power overload threshold for triggering incoming handover to the TRX under the prerequisite that the power amplifier
of the TRX provides the maximum output power.
Initial coding mode used for full rate AMR calls. The four values 0, 1, 2, and 3 of this parameter respectively
represent the lowest, low, high, and highest coding rates in the ACS.
Initial coding mode used for half rate AMR calls. The four values 0, 1, 2, and 3 of this parameter respectively
represent the lowest, low, high, and highest coding rates in the ACS.
Initial coding mode used for broadband AMR calls. The three values 0, 1 and 2 of this parameter respectively
represent the lowest, low and highest coding rates in the ACS.
Specifies the timeslot mask in BSC6900
Whether to assign channel requests in the overlay subcell to the underlay subcell according to "UL Subcell Lower
Load Threshold". If the load of the underlay subcell is lower than "UL Subcell Lower Load Threshold", incoming calls
Whether to allow underlay-to-overlay edge handovers
Index of the cell in the BSC
Name of the cell in the BSC
Whether to allow underlay-to-overlay load handovers
Overlay-to-underlay load handovers are performed by levels. This parameter indicates the duration of each level.
Level step during overlay-to-underlay hierarchical load handovers
In an enhanced dual-band network, if the load of the overlay subcell is higher than this parameter, the system cannot
initiate an underlay-to-overlay handover.
Incoming BSC6900 port number
Number of a BTS port
In-port number of a DXX
Mode of inputting the latitude and longitude of a cell location
Whether to allow inter-BSC SDCCH handovers
Incoming BSC6900 slot number
Number of the in-port slot on a BTS
Incoming BSC6900 subrack number
Number of the in-port subrack on a BTS
Time interval for sending a simple cell broadcast message
Hysteresis value during the handovers between cells on different layers or of different priorities. This value is used to
suppress inter-layer ping-pong handovers.
Type of an interference band statistics algorithm used when the frequency scanning function is enabled. The
interference band statistics algorithm I uses pair average, and the interference band statistics algorithm II uses linear
Reduces ping-pong handovers between cells on a same layer. This parameter is invalid when cells are on different
layers.
Specifies an interval between two consecutive interference handovers
The triggering of interference handovers must meet the P/N criteria, that is, when P out of N measurement reports
meet the condition for interference handovers, a concentric circle handover is triggered. This parameter corresponds
The triggering of interference handovers must meet the P/N criteria, that is, when P out of N measurement reports
meet the condition for interference handovers, a concentric circle handover is triggered. This parameter corresponds
Whether to allow the interference handover algorithm. Interference handovers are triggered when the receive level is
higher than the receive threshold while the transmit quality is lower than the interference handover quality threshold,
Whether to consider interference priorities during channel assignment
Threshold used for interference measurement.
The BSS measures the uplink quality of the radio channels occupied by MSs, and calculates and reports the
Threshold used for interference measurement.
The BSS measures the uplink quality of the radio channels occupied by MSs, and calculates and reports the
Threshold used for interference measurement.
The BSS measures the uplink quality of the radio channels occupied by MSs, and calculates and reports the
Threshold used for interference measurement.
The BSS measures the uplink quality of the radio channels occupied by MSs, and calculates and reports the
Threshold used for interference measurement.
The BSS measures the uplink quality of the radio channels occupied by MSs, and calculates and reports the
Threshold used for interference measurement.
The BSS measures the uplink quality of the radio channels occupied by MSs, and calculates and reports the
Value of the timer for synchronization between BSCs. If a BSC fails to synchronize with the control BSC before the
timer expires, the BSC starts to synchronize the BTSs under its control.
Period during which interference levels are averaged. The interference levels on idle channels are averaged before
the BTS sends a radio resource indication message to the BSC6900. The averaging result is used for classifying the
This parameter specifies whether the reselection from 2G cells to 3G cells is allowed.
Threshold for setting the flag of accepting inter-RAT CS service handover of a 2G cell
This parameter specifies whether the handover from 3G cells to 2G cells is allowed.
Whether to reserve resources for the incoming BSC handover on the Iur-g interface
Width of load band [EcNo] during the inter-RAT hierarchical load-based handover
Initial EcNo value of the inter-RAT load-based handover band
Step of changing the EcNo value during the inter-RAT hierarchical load-based handover
Width of load band [RSCP] during the inter-RAT hierarchical load-based handover
Initial RSCP value of the inter-RAT load-based handover band
Step of changing the RSCP value during the inter-RAT hierarchical load-based handover
This parameter specifies whether the handover from 2G cells to 3G cells is allowed.
When this parameter is set to Service-based, the inter-RAT handover is triggered on the basis of the service
distribution. In this case, the target cell is selected according to the traffic load.
Time span before the command is executed. The logs generated within the time span are to be exported.
Interval for sending packets to test Ethernet OAM loop
Frequency index of the interference measurement in type 3 of an extension measurement report
Lower threshold of the overlay level during underlay-to-overlay handovers. When the receive level of an MS is higher
than this threshold, the MS can be switched to the overlay subcell.
The timer is used to set the time when the BSC6900 waits for an Internal Handover Command message after a
Internal Handover Required message is reported in an internal BSC handover when A interface is IP. If the timer
Timer started after the BSC6900 delivers a handover command in an intra-BSC inter-cell handover. If the BSC6900
receives a handover complete message before this timer expires, the timer stops. If this timer expires, the BSC6900
Whether to allow AMR handovers. This parameter has no impact on dynamic non-AMR F-H handovers.
This parameter specifies whether the intra-cell handover is enabled. Note: A forced intra-cell handover is not subject
to this parameter.
Timer started after the BSC6900 delivers a handover command in an intra-BSC intra-cell handover. If the BSC6900
receives a handover complete message before this timer expires, the timer stops. If this timer expires, the BSC6900
Whether it is an RNC under the same MBIC in GU mode
Minimum Ec/No value of a 3G cell during the load-based GSM-to-UMTS handover
When the load of a cell is greater than or equal to Load HO Threshold, all the calls in the serving cell send handover
requests simultaneously. Thus, the load on the CPU increases rapidly. In some cases, the cell is congested and call
Minimum RSCP value of a 3G cell during the load-based GSM-to-UMTS handover
Incoming BSC6900 start timeslot number
Number of a DXX In-timeslot
Interval for executing the scheduled subtask. If the time mode is set to "DAILY_C", "WEEKLY_C", or "MONTHLY_C",
you should set this parameter.
Automatic switchover interval. This parameter needs to be set only when "OMU automatic switchover switch" is set to
"ON". The minimum automatic switchover interval is 30 days and the maximum automatic switchover interval is 1024
Whether a measurement report can contain the information about a cell with an invalid BSIC. The cell with an invalid
BSIC is an unconfigured neighboring cell.
IP address
IP address of the server
IP address of the local NSVL
IP address of the remote NSVL
IP address of a BTS port. It cannot be the same as any IP address configured in the BSC6900.
IP address of the FTP server. When the FTPServer.exe file is downloaded through the FTP Tool button on the LMT,
the address of the FTP server is the same as that of the LMT client.
The local IP address must be the configured IP address (including the IP address and port address of the interface
board).
IP address of the board
Local IP address of the Ethernet port
Source IP address of the packet for preventing the ICMP attack
IP address of the next hop
Local IP address of the aggregation group
IP address of the router
First IP address of the SGSN
It must be the valid address of the A, B, or C type and cannot be the broadcast address or network address.
Second IP address of the SGSN
It must be the valid address of the A, B, or C type and cannot be the broadcast address or network address.
Third IP address of the SGSN
Fourth IP address of the SGSN
When the number of error frames on the IP layer reaches the value of this parameter, the frame error alarm is
generated.
When the number of error frames on the IP layer decreases to the value of this parameter, the frame error alarm is
cleared.
Whether to compress the packet headers
Whether to compress the IP header of a MP group
IP address index of the Ethernet port
IP address index of the aggregation group
IP packet multiplex index
Type of the physical IP transmission medium
Type of IP physical transmission cable medium, E1 or FE/GE.
Whether to enable the heater.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether the BSC is a reference BSC
Whether the cell is a chain neighboring cell. The parameter is used in the quick handover algorithm. Quick handover
aims to increase the handover success rate of an MS moving at a high speed and to ensure the call continuity and
Whether to support clock server redundancy configuration
Whether to support clock server redundancy configuration
Whether to enable the BTS to support ring networking. IP BTS does not support this parameter.
If this parameter is set to "YES", the check threshold for a specific board is used. In this case, the following
paramters are involved: Forward Bandwidth, Receive Bandwidth, Power Class, TRX Number. If this parameter is set
A service support attribute of a cell, that is, whether an external GSM cell supports EDGE
Whether to indicate the first class transport resource group
A service support attribute of a cell, that is, whether an external GSM cell supports GPRS
Whether to enable the TRX to carry the main BCCH in the cell
Whether a BSC in the TC pool is the primary BSC
Whether this location group is the main location group. If the value is Yes, this location group is the main location
group. If the value is No, this location group is the slave location group.
A service support attribute of a cell, that is, whether an external GSM cell supports NC2
Configuration mode of the IP subnetwork. Static configuration: fixed local NSVL and remote NSVL parameters
through manual configuration; Dynamic configuration: the NSVL parameter obtained through negotiation between the
Whether it is QOSPATH
Whether the Um interface software synchronization between BSCs is supported
Whether multiple DEMUs are configured
ISSUPERBTS
Whether to enable the BTS to support local switching
If the BTS supports local switching, when the calling and called MSs are both within the BTS or BTS group, the voice
Whether to support the TC pool function. The TC Pool feature is implemented by connecting the maim processing
subracks (MPSs) and extended processing subracks (EPSs) in multiple BSC6900s to the transcoder subracks
Whether it is a TC board.If the board is for the TC subrack, set the parameter to YES.
If the board is not for the TC subrack, set the parameter to NO.
Whether the subrack is a remote main TC subrack
Whether to control the temperature difference between the air inlet and air outlet and that between the air outlet and
ambient by the temperature control system.
Whether to configure the transmission cabinet. The BTS uses this parameter to calculate the number of TRXs to be
shut down.
Number of a row to be changed in a BA list
Reserved parameter for cells. There are 30 parameters of this type, which can be used as new parameters in later
versions.
Used for parameter control
Value of a reserved parameter for cells
Type of the adjacent node
Type of the interface. This is determined by the type of the protocol currently used by the BTS. Point-to-Point
Protocol (PPP) is a data link protocol. Multilink PPP (MP) is a bandwidth-on-demand protocol that binds multiple links
Concentric cell attributes of TRX. If the cell where a TRX is located is configured as a concentric cell, set this
parameter to OVERLAID or UNDERLAID as required. If the cell where a TRX is located is not configured as a
Conversion policy of the dynamic channel of the concentric cell
The triggering of concentric circle handovers must meet the P/N criteria, that is, when P out of N measurement
reports meet the condition for concentric circle handovers, a concentric circle handover is triggered. This parameter
The triggering of concentric circle handovers must meet the P/N criteria, that is, when P out of N measurement
reports meet the condition for concentric circle handovers, a concentric circle handover is triggered. This parameter
Whether a cell is a normal cell, concentric cell, or enhanced dual band network cell.
In a concentric cell, the coverage areas of different TRXs form concentric circles of different radiuses.
Switch for the J0 tracing mark mismatching alarm
Byte display format of J0
Expected receiving value of J0. J0 byte, also called the trace byte of the regenerator section on the optical port
(RTIM), is one of the optical port interconnection parameters. The BSC receives the peer J0 byte continuously.
Sending value of J0. J0 byte, also called the trace byte of the regenerator section on the optical port (RTIM), is one
of the optical port interconnection parameters that is continuously transmitted to the peer end. This parameter
J0 type
Switch for the J1 tracing mark mismatching alarm
Byte display format of J1
Expected receiving value of J1. J1 byte, also called the trace byte of the high-order path on the optical port, is one of
the optical port interconnection parameters. The local end continuously receives the peer J1 byte.
Sending value of J1. J1 byte, also called the trace byte of the high-order path on the optical port, is one of the optical
port interconnection parameters transmitted to the peer end continuously. This parameter enables the peer end to
J1 type
Switch for the J2 tracing mark mismatching alarm
Byte display format of J2
Byte length of J2
Expected receiving value of J2
Sending value of J2
A zero or a space used to fill in the J byte of the optical port based on the J byte of the peer equipment. If the J bytes
are inconsistent, an alarm related to J byte mismatch will be reported and the negotiation of the optical port may fail,
Whether to enable the LAPD Jitter Buffer algorithm. This algorithm adds a buffering adaptation layer under the LAPD
layer at the receiving end. The function at this layer is to delay the I frame (first received, last sent) currently
Default receive delay of the PS Jitter Buffer on the BTS. A greater value of this parameter indicates a longer end-to-
end delay for the PS service.
Whether the LAPD Jitter Buffer is enabled on the BSC side
Determines whether the last three bits of K2 indicates the single end and the dual end
K offset used in K sequencing. To reduce ping-pong handovers, the system performs K sorting based on the
downlink receive level of the candidate cells. But before doing that, the system subtracts "K Bias" from the actual
Duration of the PPP/MP link keep-alive timer
Location area code (LAC). MSs can freely move in the local location area with no need of location update.
Reasonable local allocation can effectively lighten the signaling load and improve the call completion rate.
Location area code (LAC). The MS can move within the local location area without location update. The reasonable
classification of the location area is very important for reducing the signaling load and improving the put-through rate.
Aggregation mode. When this parameter is set to static aggregation, the LACP protocol is activated; otherwise, the
LACP protocol is deactivated.
Decimal value when the latitude where a cell is located is indicated in the format of degree
Decimal value when the longitude where a cell is located is indicated in the format of degree
Integer value when the latitude where a cell is located is indicated in the format of degree
Value of the minute part when the latitude is indicated in the format of degree_minute_second
Decimal value of the second part when the latitude is indicated in the format of degree_minute_second
Integer value of the second part when the latitude is indicated in the format of degree_minute_second
Longitude of the GPS receiver antenna
Longitude of the GPS receiver antenna
Delay statistics period. This parameter indicates the period to collect the statistics information about the link
transmission delay. Note that the unit of this parameter is 100 milliseconds. The actual delay statistics period is the
Number of delay adjustment suspension periods. This parameter specifies the delay statistics periods in which the
bandwidth is not adjusted when the bandwidth adjustment function of the logical port is triggered due to the change
Bandwidth reduction delay threshold. This parameter is used to trigger the function of bandwidth reduction at the
logical port when the link delay exceeds the value of this parameter.
Average delay reduction filtering index
Average delay increase filtering index
Layer where a cell is located. The network designed by Huawei has four layers: Umbrella (layer 4), Macro (layer 3),
Micro (layer 2), and Pico(layer 1). Each layer can be set with 16 priorities.
A network basically consists of four layers, namely, Umbrella, Macro, Micro, and Pico. Cell priorities influence the
sorting of neighboring cells during handovers as well as handover algorithms including PBGT and inter-layer
When the load of the serving cell reaches the threshold, the inter-layer handover algorithm takes effect. Through
configuration of the parameter, the handover to a lower-layer cell for load-sharing is performed only when the load of
Timer of increasing the Lb flow control level when the BSC receives an SMLC congestion indication. If the BSC
receives another SMLC congestion indication before the timer expires, the flow control level remains unchanged.
Timer of decreasing the Lb flow control level. If no SMLC congestion indication is received within the valid period of
the timer, the BSC decreases the flow control level by one until the flow control level is decreased to 0.
Fourth action taken for load control
First action taken for load control
Second action taken for load control
The local entity number uniquely identifies a local entity.
Level of the log
Log level to be collected.
Alarm mask switch
Class of the maintenance domain
Whether to support the reporting of the main diversity level
Whether to allow inter-layer and inter-level handovers. The inter-layer and inter-level handover algorithm is achieved
through the setting of different layers and priorities for cells, which switches traffic to cells of a higher precedence
Hysteresis value during the handovers between cells on different layers or of different priorities. This value is used to
suppress inter-layer ping-pong handovers.
The triggering of inter-layer handovers must meet the P/N criteria, that is, when the condition for inter-layer
handovers is met for a consecutive P seconds during N seconds, an inter-layer handover is triggered. This
The triggering of inter-layer handovers must meet the P/N criteria, that is, when the condition for inter-layer
handovers is met for a consecutive P seconds during N seconds, an inter-layer handover is triggered. This
Logical function type of the board
OAM:Operation And Maintenance Process
Logical function type of the board
Logical function type
Application type of the POUc_TDM board
The Logical Index of PB signaling link
Lower humidity threshold for the environment alarm box to report an alarm indicating that the ambient humidity is too
low. If the ambient humidity of the BTS is lower than this threshold, the environment alarm box reports the alarm.
The occur threshold of 20258 alarm,you can set it from 90% to 99%
The recover threshold of 20258 alarm,you can set it from 90% to 99%
Key field used to identify one LAPD link
Type of the parameters to be displayed when a cell template is queried. The value "DIFFERENCE" indicates that the
parameters in the cell template that are different from those in the default template are displayed. The value "ALL"
Rate type of the designated link
Lower limit for triggering an alarm
Lower limit of an alarm. It is valid for the analog port.
The loopback channel number when the port loopback mode is set to single channel local loopback
Upper threshold of the low noise amplifier. When the working voltage of the low noise amplifier attenuator in the RXU
board is smaller than this value, an alarm is reported by the BTS.
Lower threshold of the low noise amplifier. When the working voltage of the low noise amplifier attenuator in the RXU
board is greater than this value, an alarm is reported by the BTS.
Optical interface tributary numbering method. This parameter indicates the sequence of tributaries in an SDH frame.
Rate of the semipermanent link
Initial bearing tag of the M3UA link. This parameter can be set to either active mode or standby mode. For details
about the relevant bearer tag, see the the parameter "Traffic mode" of the "ADD M3LKS".
Link load sharing. In the value, the number of 1s (represented by n) determines the maximum number (2^n) of links
for the load sharing. For example, B0000 indicates that up to one link is used for the load sharing, B0001 and B1000
Signaling link mask corresponding to the M3UA link set. It is used for the M3UA link load sharing. It is valid only
when the working mode of the signaling link set is set to load sharing. In the value, the number of 1s (represented by
If the load of a cell is lower than the value of this parameter, the cell can admit the users handed over from other
cells with higher load. Otherwise, the cell rejects such users.
Type of load balancing algorithm of the MSC Pool. Generally, the BSC6900 chooses an MSC according to the
obtained network resource indication (NRI). In some cases, however, the BSC6900 cannot do so. Instead, the
Intervals that the BSC broadcasts a cell's traffic load to its neighbor cells. The uplink load and downlink load indicate
the traffic situation of a cell. The uplink load = number of uplink TBFs carried on all PDCHs in a cell / total number of
Load current shunt coefficient
This parameter specifies whether to use the load handover or the enhanced load handover.
This parameter specifies whether a traffic load-sharing handover is enabled. The load handover helps to reduce cell
congestion, improve success rate of channel assignment, and balance the traffic load among cells, thus improving
Indicates that if a 2G neighboring cell supports load handovers, the BSC adds the load information of the local cells
in the signaling procedures related to this neighboring cell.
Indicates that if a 3G neighboring cell supports load handovers, the BSC adds the load information of the local cells
in the signaling procedures related to this neighboring cell.
If the path loss in the serving cell minus that in a handover candidate cell is not smaller than the parameter value, the
handover to the candidate cell is allowed. The parameter loosens the requirement of the PBGT handover threshold
After a load handover succeeds, the BSC punishes the former serving cell during "Penalty Time on Load HO" by
subtracting "Penalty Value on Load HO" from the receive level of the former serving cell, thus avoiding ping-pong
After a load handover succeeds, the BSC punishes the former serving cell during "Penalty Time on Load HO" by
subtracting "Penalty Value on Load HO" from the receive level of the former serving cell, thus avoiding ping-pong
When the load of a cell reaches or exceeds "Load HO Threshold", all the calls that are using this cell as the serving
cell generate handover requests at the same time, which will suddenly increase the load of the processor. Under
In hierarchical load handovers, starting from "Edge HO DL RX_LEV Threshold", a "Load HO Step Level" is added to
the upper handover threshold after every "Load HO Step Period". In this way, all the calls in the current serving cell
This parameter specifies the ratio of the MSs that simultaneously perform a load handover. You can enlarge the ratio
to accelerate the handover to a neighboring cell for load sharing. Too large a ratio, however, causes the neighboring
In the handover algorithm of the first generation, load handovers can be performed only when the receive level of the
current serving cell is in the range "Edge HO DL RX_LEV Threshold" to "Edge HO DL RX_LEV Threshold" + "Load
Whether to enable load power-off.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether to allow the cell load reselection. If this parameter is set to PERMIT and "NC2 Load Reselection Switch" is
set to Support, the load of the target cell is involved in the algorithm for NC2 cell reselection.
Threshold for allowing the MS to reselect a cell during load reelection. When the receive level of the serving cell is
lower than this threshold, the load reselection is triggered.
When the uplink load or downlink load of the target cell is lower than this threshold, it can accept the MSs from the
serving cell due to load reselection.
When the uplink load or downlink load of the cell exceeds this threshold, the load reselection decision is made.
If this parameter is set to YES, the channel assignment algorithm II randomly selects the start range for channel
traversal; otherwise, the algorithm selects the channel next to the channel assigned last time as the start point of
This parameter specifies whether the dynamic PDCHs that have been converted into the PDCHs are considered
during the calculation of the current cell load.
TRM load threshold switch
Local BSC identity. It identifies a BSC.
Local IP address of PPP link. The IP address of the PPP link on the BSC side.
Local IP address of the MP group
Local IP address of BTS PPP Link.
Local IP address of BTS MLPPP Group.
Identifies a local NSVL
Identifies the local port of the router. The setting of this parameter must be consistent with the setting at the SGSN
side.
Number of the location group under the BTS. It is unique for each BTS.
Number of a location group
The value of this parameter can include one or two conditions.
"&" is used to concatenate the conditions, and the records are obtained when the two conditions are matched.
Identifies the first local IP address that communicates with the peer end. When it is set to 0, it is invalid. This IP
address must be first configured on the corresponding interface board.
Identifies the second local IP address that communicates with the peer end. When it is set to 0, it is invalid. This IP
address must be first configured on the corresponding interface board.
Whether to lock all the non-default local accounts
Local SCTP port number
Board start load control
Mode of software loading
CPU usage threshold for log flow control. When the average CPU usage of sliding windows reaches or exceeds the
threshold, log flow control is triggered.
Packet queue usage threshold for log flow control. When the average packet queue usage of sliding windows
reaches or exceeds the threshold, log flow control is triggered.
Whether the SCTP is bound to a logical port. For details, see "ADD IPLOGICPORT".
Logical port No. bound by the SCTP. For details, see the parameter "Logic port No." of the "ADD IPLOGICPORT".
Logical port slot No. bound by the SCTP. For details, see the parameter "Slot No." of the "ADD IPLOGICPORT".
CPU usage threshold for recovery from log flow control. When the average CPU usage of sliding windows is lower
than the threshold, log flow control is triggered.
Packet queue usage threshold for recovery from log flow control. When the average packet queue usage of smooth
windows is lower than the threshold, log flow control is triggered.
Whether to control the log flow
The log type to be collected.
Type of the log. "COMLOG" indicates a common log. "CMPLOG" indicates a compressed log.
Decimal value when the longitude where a cell is located is indicated in the format of degree
Value of the degree part when the latitude is indicated in the format of degree_minute_second
Integer value when the longitude where a cell is located is indicated in the format of degree
Value of the minute part when the longitude is indicated in the format of degree_minute_second
Decimal value of the second part when the longitude is indicated in the format of degree_minute_second
Integer value of the second part when the longitude is indicated in the format of degree_minute_second
Latitude of the GP receiver antenna
Latitude of the GPS receiver antenna
Loop level
Loop type
1. Local loop:Make loop test on the local board at system side, while the system platform will send test frames.
Loop Detect Switch
Loopback type of LAPD link
When the load of an SDCCH on the TRX that is in loose frequency reuse and is in the compatible band of the BCCH
is lower than this threshold, the SDCCH is preferably allocated.
Direction of an external voice loop
Loopback point. There are 14 loopback points. Whether a loopback point is available depends on the subrack
configuration mode in the BSS and the transmission mode of each interface. The details are as follows:
Loopback type
Loopback type
Time of an external voice loop
Number of suspension periods after the bandwidth adjustment is performed based on the packet drop ratio. This
parameter specifies the delay statistics periods in which the bandwidth is not adjusted when the bandwidth
Whether to permit the preemption of lower-level sublink resources. If the value of this parameter is YES, a CS
domain service can preempt the sublink resources of the PS domain services on the lower-level BTS of the
The CS services are preferred. This parameter indicates that the CS services are permitted to preempt the dynamic
Abis resources on the sublink of the current level site.
Whether to permit the low noise amplifier (LNA) bypass
Whether to assign overlay channels in an IUO cell based on the receive level conditions
Whether to power off the TRX in the case of overlow temperature of the BTS cabinet.
If this parameter is set to "Yes", the BTS powers off the TRX and reports a "Load Power Off Alarm" to protect the
Whether to power off the TRX of a BTS when the temperature of the BTS cabinet is too low.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Loopback mode
Number of the IP logical port that carries the IP path
Logical port number
Logical port number
Number of the IP logical port that carries the IP path
Type of logical port
It is applicable to the radio transmission environment to improve the link quality. Link adaptation (LA) indicates
adjusting the coding mode of the channel dynamically according to the transmission quality of the link. The link
Whether to enable power shutdown upon low voltage of the battery.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Load power-off voltage threshold. If "Load Shutdown Flag" is set to "Enable" and the load voltage is lower than the
value of this parameter, the load is automatically powered off.
Third action taken for load control
Whether to include the list command
Query results can be displayed vertically or horizontally
Format of the result list
Loading type
Type of the log
Type of the log
Temperature control threshold for low temperature. When the ambient temperature is less than "Low Temperature
Critical Point", the temperature control system needs to control the temperature difference between the air inlet and
Lower temperature threshold for the environment alarm box to report an alarm indicating that the ambient
temperature is too low. If the ambient temperature of the BTS is lower than this threshold, the environment alarm box
Lower voice quality threshold associated with the automatic adjustment of the AMR handover uplink threshold;The
value of this parameter must be smaller than or equal to the value of Uplink Long-term FER Target.
Target voice quality value associated with the automatic adjustment of the uplink threshold of AMR handover
Upper voice quality threshold associated with the automatic adjustment of the AMR handover uplink threshold
Factor of uplink threshold adjustment. It indicates the linear relation between the threshold adjustment value and the
logarithmic FER.
Number of DSPs, each of which carries 252 LVDS links on the DPUd or DPUb board. If this parameter is set to 0,
every DSP carries 192 LVDS links by default.
The level 1 Voltage Standing Wave Ratio (VSWR) threshold. When the VSWR is higher than this parameter, the
TRX will report a level-1 VSWR alarm. At this time, the BTS can provide services but its coverage rate decreases.
The level 2 Voltage Standing Wave Ratio (VSWR) threshold. When the VSWR is higher than this parameter, the
TRX will report a level-2 VSWR alarm. At this time, the BTS disables power amplification and fails to provide
Whether "Shutdown Voltage" is valid.
In multi-mode base station scenario, the value of this parameter in different modes must be the same for the same
Number of the M3UA service listening port
MAC address of the VLAN
When the number of error frames on the MAC layer reaches the value of this parameter, the frame error alarm is
generated.
When the number of error frames on the MAC layer decreases to the value of this parameter, the frame error alarm
is cleared.
Coding mode in which an ARFCN is sent to an MS during an assignment or handover. If the parameter is set to
CA_MA, an ARFCN is indicated through the CA and MA information contained in an assignment or handover
Identifies a maintenance group.
Maintenance group: maintenance alliance (MA), which is a component of the maintenance domain (MD).
When this parameter is set to YES, the BSC6900 is allowed to reduce the transmit power of the non-BCCH timeslots
on the BCCH TRX.
This parameter specifies whether to enable the Enhanced BCCH Power Consumption Optimization feature.
Generally, the BCCH TRX transmits signals at the maximum transmit power. When this parameter is set to YES, the
This parameter specifies the end time of the period during which the power of the non-BCCH timeslots on the BCCH
TRX is derated.
This parameter specifies the range of power derating over the non-BCCH timeslots on the BCCH TRX.
This parameter specifies the start time of the period during which the power of the non-BCCH timeslots on the BCCH
TRX is derated.
Bar code 1 of the interface board of the BTS. This parameter is the electronic serial number of the active PTU board.
An electronic serial number uniquely identifies an PTU board. This parameter is set before delivery.
Bar code 1 of the BTS interface board
Number of main location group. Each cell contains only one main location group.
Number of the port to which the active OML of the BTS is connected
Main version No. of the TMU board software. It is configured according to the actual situation.
Mobile allocation index offset 1. Start frequency number, which is the number of the frequency where frequency
hopping starts
Mobile allocation index offset 10. Start frequency number, which is the number of the frequency where frequency
hopping starts
Mobile allocation index offset 11. Start frequency number, which is the number of the frequency where frequency
hopping starts
Mobile allocation index offset 12. Start frequency number, which is the number of the frequency where frequency
hopping starts
Mobile allocation index offset 2. Start frequency number, which is the number of the frequency where frequency
hopping starts
Mobile allocation index offset 3. Start frequency number, which is the number of the frequency where frequency
hopping starts
Mobile allocation index offset 4. Start frequency number, which is the number of the frequency where frequency
hopping starts
Mobile allocation index offset 5. Start frequency number, which is the number of the frequency where frequency
hopping starts
Mobile allocation index offset 6. Start frequency number, which is the number of the frequency where frequency
hopping starts
Mobile allocation index offset 7. Start frequency number, which is the number of the frequency where frequency
hopping starts
Mobile allocation index offset 8. Start frequency number, which is the number of the frequency where frequency
hopping starts
Mobile allocation index offset 9. Start frequency number, which is the number of the frequency where frequency
hopping starts
Critical alarm threshold against excessive TMA feed current of feed tributary 0. When the actual current is greater
than the specified value, a TMA feed current critical alarm is generated.
Critical alarm threshold against excessive TMA feed current of feed tributary 1. When the actual current is greater
than the specified value, the TMA feed current critical alarm is generated.
Critical alarm threshold against excessive TMA feed current of feed tributary 2. When the actual current is greater
than the specified value, the TMA feed current critical alarm is generated.
Critical alarm threshold against excessive TMA feed current of feed tributary 3. When the actual current is greater
than the specified value, the TMA feed current critical alarm is generated.
Critical alarm threshold against excessive TMA feed current of feed tributary 4. When the actual current is greater
than the specified value, the TMA feed current critical alarm is generated.
Critical alarm threshold against excessive TMA feed current of feed tributary 5. When the actual current is greater
than the specified value, the TMA feed current critical alarm is generated.
Name of the MA
Name of the maintenance association.
Subnet mask corresponding to the local IP address of the PPP link
Subnet mask of the MP group in BSC.
Subnet mask of the board
Mask of the source IP network segment of the packet against the ICMP attack
Subnet mask
Subnet mask of the CBC
IP subnet mask of a BTS port
Subnet mask of BTS PPP link.
Subnet mask of BTS MLPPP Group.
IP address of the main clock server. It must be a legal A/B/C type address but not a broadcast address or network
address.
It must be the valid address of the A, B, or C type and cannot be the broadcast address or network address.
Step of upward power adjustment according to the quality of the received signals
If the number of the association retransmissions exceeds this value, the parameter is deleted automatically. The
value must be greater than Path max retrans.
Maximum bandwidth for dynamic adjustment at the logical port
Number of consecutive intra-cell handovers allowed in a cell. When the interval between two intra-cell handovers is
lower than a certain time threshold, these two intra-cell handovers are considered consecutive. When a certain
Maximum number of attempts to resend the downlink assignment messages
Number of attempts to re-establish the downlink TBF
This parameter specifies the largest step of each TRX power reduction.
Maximum number of TRXs that can be configured for one cell. For the BTS3900B GSM, when the "Frequency and
BSIC Plan Switch" is ON, the "Maximum TRX Number" (one or two, one by default) can be selected. For the
Maximum number of TRXs that can be configured for one cell. For the BTS3900B GSM, when the "Frequency and
BSIC Plan Switch" is ON, the "Maximum TRX Number" (one or two, one by default) can be selected. For the
Maximum multiplexing frame length.
Maximum number of BTSs that are allowed to concurrently download software under a BSC
The value of this parameter cannot be less than the maximum PPPMUX sub-frame length (MUXMAXSFL). This
parameter can be associated with the maximum segment length of the MP to control whether to segment the
Maximum length of the PPP multiplexing frame
Maximum number of retries when the user logs in
Maximum capacity for storing the alarm log
Maximum output power of the diesel
If the number of the path retransmissions exceeds this value, the parameter is deleted automatically. The value must
be smaller than Association max retrans.
Retransmission times of Pb link check (LapdCheck) messages. When a BSC sends a Pb link check message to an
external PCU and fails to receive a response from the external PCU, it retransmits the message. This parameter
Maximum number of PDCHs that can be assigned in the TRX
Maximum value of the PDCH ratio in a cell. The number of available TCHs and PDCHs in a cell is set to a fixed
value. The PDCH ratio is: Number of available PDCHs/(Number of available TCHFs + Number of available static
Maximum number of attempts to resend the polling messages
Expire Prompt Dates.
Maximum current coefficient when the battery is charged. When the battery is charged, the maximum current can be
0.01 to 0.99 times of the capacity of the battery cabinet. That is, the charge coefficient is 0.01-0.99. For example, if
Maximum current coefficient when the battery is charged. When the battery is charged, the maximum current can be
0.05 to 0.25 times of the capacity of the battery cabinet. That is, the charge coefficient is 0.05-0.25. For example, if
Maximum times for a Physical Information message to be transmitted. When the retransmission times exceeds this
parameter and the BTS still cannot receive any correct SAMB frame from the MS, the BTS sends a connection
Maximum retransmission for radio priority 1. The 2bit Radio Priority message carried by the MS in the Packet
Channel Request message has four levels of priorities. Level 1 is the highest priority, and level 4 is the lowest
Maximum retransmission for radio priority 2. The 2bit Radio Priority message carried by the MS in the Packet
Channel Request message has four levels of priorities. Level 1 is the highest priority, and level 4 is the lowest
Maximum retransmission for radio priority 3. The 2bit Radio Priority message carried by the MS in the Packet
Channel Request message has four levels of priorities. Level 1 is the highest priority, and level 4 is the lowest
Maximum retransmission for radio priority 4. The 2bit Radio Priority message carried by the MS in the Packet
Channel Request message has four levels of priorities. Level 1 is the highest priority, and level 4 is the lowest
Maximum PPPMUX sub-frame length. If the PPP frame length is larger than this value, the PPPMUX multiplexing is
performed. The value of this parameter cannot be larger than the maximum multiplexed frame length wMuxMfl. To
Maximum length of the PPP multiplexing frame
Huawei power control algorithm II divides three quality zones according to the quality of the receive signals. When
the power is downwardly adjusted according to the level, the maximum downward adjustment step can vary
Huawei power control algorithm II divides three quality zones according to the quality of the receive signals. When
the power is downwardly adjusted according to the level, the maximum downward adjustment step can vary
Huawei power control algorithm II divides three quality zones according to the quality of the receive signals. When
the power is downwardly adjusted according to the level, the maximum downward adjustment step can vary
This parameter specifies the actual coverage area of a cell. After receiving the channel request message or
handover access message, the BTS determines whether the channel assignment or handover is performed in the
Number of measurement reports (MRs) used for averaging the time advance before the call drops
Whether to initiate a forcible call drop when the time advance exceeds "MAX TA Drop Call Threshold"
Whether the time advance after filtering exceeds the threshold. If the threshold is exceeded, a forcible call drop is
initiated.
Maximum positioning time.
Maximum number of (16 kbit/s) Abis timeslots that the PDCHs can use in the TRX
Maximum TTL value of the sent TRACERT packet
Step of upward power adjustment according to the quality of the received signals
Maximum Valid Dates.
Detection index. The index is a unique value ranging from 0 to 31 if it is not specified.
Local IP address for multi-hop BFD
Used for requesting the MS to report the measurement information of neighboring cells in multiple frequency bands.
This parameter is carried in the system information 2ter and 5ter.
For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured
values in several consecutive measurement reports. This parameter indicates the number of enhanced
For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured
values in several consecutive measurement reports. This parameter indicates the number of enhanced
Number of the BTS. The BTS is numbered uniquely in a BSC.
Name of the BTS. The BTS is named uniquely in a BSC.
Mobile country code. This parameter identifies the country where a mobile subscriber is located, for example, the
Chinese MCC is 460.
Local mobile country code (MCC). It is used to identify the country that the mobile subscriber belongs to. For
example, the MCC of China is 460.
Number of MC priorities. This parameter is valid when the MP group type is MC.
Number of MC prioritie levels.
Number of the cell. The cell is numbered uniquely in a BSC.
Name of cell 2
Cabinet No. of the management board. The management board refers to the TMU or RXU that directly
communicates with the board. The configuration of this parameter must be consistent with the actual physical
If the MCPA Optimization Switch is turned on, the MCPA priority update mode is adjusted.
Standard for the GSM multi-carrier BTS
Identifies a maintenance domain
Level of the maintenance domain.The priority of the maintenance domain ranks from 0 to 7 from low to high.
name of the MD
Name of the maintenance domain.
Whether to allow the MS to the send the PS measurement report to the network side
Common measurement period
Type of the measurement report (MR) reported by the MS
Identifies a maintenance point in the maintenance alliance
A maintenance point is an edge node of the MA.
Identifies a maintenance end point (MEP) of a maintenance association.
The type of the maintenance point added to the maintenance group. LocalMep indicates a local maintenance point
and RemoteMep indicates a remote maintenance point.
MP/MC sequence header option
Frame encapsulation format supported by MP/MC.
Minimum receive level for a neighbor cell to become a candidate cell during cell reselection. When the receive level
of the serving cell is lower than the value of this parameter, it indicates that the normal cell reselection level is bad. In
Minimum bandwidth for dynamic adjustment at the logical port
Selects 3G candidate cells. If the measured value of a 3G neighboring cell is lower than this threshold, the 3G
neighboring cell will be removed from among the 3G candidate cells.
Minimum receive level offset.
An MS can be handed over to a neighboring cell only when the downlink level of the neighboring cell is greater than
Threshold for triggering prompt alarm clearance when the ANT_A tributary antenna current is too heavy. When the
actual current is higher than the configured value, the ALD Current Prompt Alarm clearance is triggered.
Threshold for triggering prompt alarm clearance when the ANT_B tributary antenna current is too heavy. When the
actual current is higher than the configured value, the ALD Current Prompt Alarm clearance is triggered.
Warning alarm threshold against excessive TMA feed current of feed tributary 0. When the actual current is greater
than the specified value, a TMA feed current warning alarm is generated.
Warning alarm threshold against excessive TMA feed current of feed tributary 1. When the actual current is greater
than the specified value, the TMA feed current warning alarm is generated.
Warning alarm threshold against excessive TMA feed current of feed tributary 2. When the actual current is greater
than the specified value, the TMA feed current warning alarm is generated.
Warning alarm threshold against excessive TMA feed current of feed tributary 3. When the actual current is greater
than the specified value, the TMA feed current warning alarm is generated.
Warning alarm threshold against excessive TMA feed current of feed tributary 4. When the actual current is greater
than the specified value, the TMA feed current warning alarm is generated.
Warning alarm threshold against excessive TMA feed current of feed tributary 5. When the actual current is greater
than the specified value, the TMA feed current warning alarm is generated.
Threshold for triggering prompt alarm clearance when the ANT_A tributary antenna current is too heavy. When the
actual current is lower than the configured value, the ALD Current Prompt Alarm clearance is triggered.
Threshold for triggering prompt alarm clearance when the ANT_B tributary antenna current is too heavy. When the
actual current is lower than the configured value, the ALD Current Prompt Alarm clearance is triggered.
In a direct retry, when the receive level of a neighboring cell is no smaller than this parameter, the neighboring cell
can be a candidate cell for the direct retry. The parameter is invalid in handover algorithm II.
Minimum time required for a TCH to transform to a SDCCH and then transform back to a TCH
Selects 3G candidate cells. If the measured value of a 3G neighboring cell is lower than this threshold, the 3G
neighboring cell will be removed from among the 3G candidate cells.
Minimum interval at which two BFD packets are received.
Minimum interval at which the BTS receives BFD packets
Minimum interval between sent BFD packets
Minimum interval at which the BTS sends BFD packets
Mirror destination Ethernet port number
Mirror Ethernet port number
Mirror type
Mobile network code. This parameter identifies the public land mobile network (PLMN) to which a mobile subscriber
belongs.
Mobile network code (MNC). It is used to identify the PLMN that the mobile subscriber belongs to.
Usage threshold of the CPU for calling access. If the usage of the CPU exceeds the threshold, the calling access
request is transferred to other CPU for processing.
Working mode of the system clock. Working modes of the system clock are as follows:
(1) MANUAL: In this mode, you must specify a clock source and prevent the switching of the clock source.
SCTP link work mode. Server mode: BSC6900 starts the listening and waits for the peer to send the SCTP-INIT
message. Client mode: BSC6900 actively sends the SCTP-INIT message.
Configuration mode
Working mode after switchover
Mode of file output.
Backup mode of the switch protection group
Working mode of a port. When this parameter is set to CHECK_ON_STANDBY_PORT, the connectivity check is
performed on the standby port. When this parameter is set to CHECK_ON_INDEPENDENT_PORT, the connectivity
Alarm mode of feed tributary 0. There are three alarm modes.
Alarm mode 1 has only one type of alarms. The alarm current is fixed and greater than the normal working current.
Alarm mode of feed tributary 1. There are three alarm modes.
Alarm mode 1 has only one type of alarms. The alarm current is fixed and greater than the normal working current.
Alarm mode of feed tributary 2. There are three alarm modes.
Alarm mode 1 has only one type of alarms. The alarm current is fixed and greater than the normal working current.
Alarm mode of feed tributary 3. There are three alarm modes.
Alarm mode 1 has only one type of alarms. The alarm current is fixed and greater than the normal working current.
Alarm mode of feed tributary 4. There are three alarm modes.
Alarm mode 1 has only one type of alarms. The alarm current is fixed and greater than the normal working current.
Alarm mode of feed tributary 5. There are three alarm modes.
Alarm mode 1 has only one type of alarms. The alarm current is fixed and greater than the normal working current.
Monitoring period
Monitoring duration
Month when the TMU board software is released
A quick handover can be initiated only if the rate of an MS is higher than this parameter during a certain period of
time.
When the number of error frames on the MP group reaches the value of this parameter, the frame error alarm is
generated.
When the number of error frames on the MP group decreases to the value of this parameter, the frame error alarm is
cleared.
MP group number
MP group number
Number of an MLPPP group on a BTS. It is unique in a BTS. The scope of the number of th MLPPP group in the
BTS3900 series is 0~1.
Timeslot multiplexing mode at the Abis interface of the BTS. The BTS supports two multiplexing modes: statistical
multiplexing on a 64 kbit/s timeslot and physical multiplexing on a 16 kbit/s timeslot. The first mode is further
Number of the serial port where the board is located. The management board refers to the TMU or RXU that directly
communicates with the board. The configuration of this parameter must be consistent with the actual physical
Is Support MCPPP.
MP type
Number of the slot where the MPU subsystem is located
Number of the subrack where the MPU subsystem is located
Whether power control algorithm II allows measurement report compensation.
When making a power control decision, the BSC retrieves a certain number of history measurement reports and
If the number of measurement reports lost consecutively is no larger than this value, linear interpolation is performed
for the values in the lost measurement reports based on the values in the two measurement reports preceding and
When the number of the lost measurement reports exceeds this parameter during a power control period, the power
control stops.
Frequency at which the BTSs submit pre-processed measurement reports to the BSC
Attenuation factor for the TMA of antenna tributary 1
Attenuation factor for the TMA of antenna tributary 2
Switch of measurement report collection within a specified scope. If the specified scope is a site, the switch applies to
all the cells at the site; if the specified scope is a cell, the switch applies to the cell only. The switch of measurement
The control switch of measurement report collection includes OFF (do not collect), ON_WITH_SDCCH (collect
measurement reports for SDCCHs and TCHs), and ON_WITHOUT_SDCCH (collect measurement reports for TCHs
Maximum length of a received packet. The value of this parameter is negotiated at both ends of a communication.
Number of MSs used when the offset information is collected
Whether to collect the information about the MSs of different capabilities in a cell. This parameter has no impact on
services.
Available capacity of the MSC. This parameter is valid only when the MSC pool function is enabled. It is set
according to the actual capacity of the MSC.
Number of bits occupied by the Network Resource Identifier in the TMSI. NRI specifies a CN node in the MSC pool.
Special NRI(Network Resource Identifier) that is coded together with common NRIs. This parameter is used to
indicate that the BSC routes the service initiated by the MS to the MSC in non OFFLOAD state.
Whether to enable the MSC pool function on the BSC6900.
The MSC pool function enables up to 32 MSCs to provide services for mobile subscribers in a BSC6900. With the
Administrative state of the MSC. This parameter is valid only when the MSC pool function is enabled. It is set
according to the actual operating state of the MSC. A call accesses the MSC only when this parameter is set to
Protocol version of the MSC that is connected to the BSC6900. The supported signaling varies with the protocol
versions.
Call reestablishment timer
MSISDN value
MSISDN prefix 1. When matching the call specified by the mobile number, the BSC6900 adds the MSISDN prefix 1
according to the value of this parameter. For example, when the value of this parameter is 123 and the mobile
MSISDN prefix 2. When matching the call specified by the mobile number, the BSC6900 adds the MSISDN prefix 2
according to the value of this parameter. For example, when the value of this parameter is 123 and the mobile
MSISDN prefix 3. When matching the call specified by the mobile number, the BSC6900 adds the MSISDN prefix 3
according to the value of this parameter. For example, when the value of this parameter is 123 and the mobile
MSISDN prefix 4. When matching the call specified by the mobile number, the BSC6900 adds the MSISDN prefix 4
according to the value of this parameter. For example, when the value of this parameter is 123 and the mobile
MSISDN prefix 5. When matching the call specified by the mobile number, the BSC6900 adds the MSISDN prefix 5
according to the value of this parameter. For example, when the value of this parameter is 123 and the mobile
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If "Options for BSC Local Switch" is set to PREFIXNUMBER, and the first digits in the MSISDN of the called or
calling are the same as the value of this parameter, the BSC local switching function is enabled. For example, if two
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BSC local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BSC local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BSC local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BSC local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BSC local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BSC local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BSC local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BSC local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BSC local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BSC local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BTS local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BTS local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BTS local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BTS local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BTS local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BTS local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BTS local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BTS local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BTS local
switching function is disabled.
If the first digits in the MSISDN of the called or calling are the same as the value of this parameter, the BTS local
switching function is disabled.
Whether to enable "Triggering the quick PBGT algorithm only when an MS is far from the BTS"
Maximum number of Channel Request messages that can be sent by an MS in an immediate assignment procedure.
After the MS initiates the immediate assignment procedure, it always listens to the messages on the BCCH and all
Control command of the MSP switchover protection group
Threshold of the MS Receiver Diversity (MSRD) mode
PDCH Downlink multiplex threshold in the Mobile Station Receiver Diversity (MSRD) mode. When this parameter is
set to "80", the MS does not adopt the MSRD mode. When the number of the TBF on the PDCH that is assigned to
Number of the subrack where the board is located. The management board refers to the TMU or RXU that directly
communicates with the board. The configuration of this parameter must be consistent with the actual physical
The M criteria supports setting minimum values for the downlink receive level of neighboring cells.
The M criteria is met only when ,
When the number of received measurement reports on the downlink transmission quality (Packet Downlink Ack/Nack
message) is greater than or equal to this threshold, emergency reselection decision is made.
Duration of the flow control timer F of the MS. The MS sends the flow control message according to this duration.
If no handshake message is received from the peer within the delay, the master service is activated. A master
service object provides services at the local BSC and its configuration data is backed up at the peer BSC. A master
Maximum TX power for the MS to access the PCH
Switch for the self-healing of the OMU when the OMU process memory is overloaded
Usage threshold of the CPU for called access. If the usage of the CPU exceeds the threshold, the called access
request is transferred to other CPU for processing.
Detection method
Identify an MTP2 link
Metric system. The values of this parameter include "MET" and "IMP".
Maximum transport unit
Maximum transmission unit
Maximum size of a packet that can be transmitted or received on a FE port.
Bus voltage of the battery rack of the BTS
Multi-band point report value, including "report six cells with the strongest signal at each frequency point", "report one
cell with the strongest signal at each frequency point","report two cells with the strongest signal at each frequency
Period of performing class-1 mute detection. If the bad frame rate reaches "Bad Frame Threshold of Mute Detection
Class 1" within the period specified by this parameter, mute speech may be detected. The setting of "Mute Detection
Whether the one-way audio problem is checked in class-2 detection. In this manner, the one-way audio problems
found in class-1 are checked to ensure the accuracy.
Period of performing the class-2 mute detection. After the BTS or TC initiates a class-2 mute detection request, the
class-2 mute detection fails if there is no response and no test TRAU frame is received by the end of the period
Time for prohibiting the call from accessing the corresponding channel where one-way audio is detected on the Abis
interface.
Whether to forcibly release a call after the forced handover fails in the case of one-way audio on the Abis interface
Maximum time waiting for multiplexing
Frame timeout duration of the PPP multiplexing group
IP packet multiplexing type
Minimum number of reserved working status TRXs of the cabinet
BFD local description mark
System parameter in the LAPD protocol. The value of this parameter specifies the maximum number of times when a
frame is retransmitted.
Error control is performed on the I frame sent over the LAPDm layer between the BTS and MS. If the MS detects
errors in an I frame, the BTS should resend the I frame. This parameter indicates the maximum number of
Error control is performed on the I frame sent over the LAPDm layer between the BTS and MS. If the MS detects
errors in an I frame, the BTS should resend the I frame. This parameter indicates the maximum number of
Error control is performed on the I frame sent over the LAPDm layer between the BTS and MS. If the MS detects
errors in an I frame, the BTS should resend the I frame. This parameter indicates the maximum number of
Whether the BSC6900 sends the LAPDm N200 parameter to the BTS.
If this parameter is set to YES, the BSC sends the LAPDm N200 parameter. If this parameter is set to NO, the
Error control is performed on the I frame sent over the LAPDm layer between the BTS and MS. If the MS detects
errors in an I frame, the BTS should resend the I frame. This parameter indicates the maximum number of
Error control is performed on the I frame sent over the LAPDm layer between the BTS and MS. If the MS detects
errors in an I frame, the BTS should resend the I frame. This parameter indicates the maximum number of
Error control is performed on the I frame sent over the LAPDm layer between the BTS and MS. If the MS detects
errors in an I frame, the BTS should resend the I frame. This parameter indicates the maximum number of
Maximum value of the N3101 counter. In the dynamic uplink allocation mode, the network side enables multiple MSs
to share the same uplink channel through the USF value in the downlink data block. After the network side allocates
Maximum value of the N3101 counter. When the uplink transmission ends, if the network side receives the last RLC
data block, the network side sends an FAI=1 uplink packet acknowledged/unacknowledged message and starts
Maximum value of the N3105 counter. After the downlink TBF is set up successfully, the N3105 is started on the
network side. After the downlink RLC data block is added with the RRBP domain on the network side, the valid
Counter on the DTE side. After BC link integrity is verified according to "Parameter of DTE [N391]", the global state
query request is originated on the DTE side.
Counter on the DTE side, recording the checking times "Parameter of DTE [N393]". After BC link integrity is verified
according to "Parameter of DTE [N392]", the BC link state is restored. That is: if the BC link state on the DTE side is
Counter on the DTE side, recording the checking times "Parameter of DTE [N393]". After BC link integrity is verified
according to "Parameter of DTE [N392]", the BC link state is restored. That is: if the BC link state on the DTE side is
Whether to support the network assisted cell change (NACC). The NACC is used in the network control modes NC0,
NC1 or NC2. The NACC enables the network to notify the MS of the system information of the neighboring cell when
Name of the OSP
Name of the DSP
Name of an MTP3 route
Name of the signalling link set
Name of the MTP3 link
Name of the adjacent node
Local entity name. The local entity name must be unique.
Name of the destination entity
The M3UA route names and the M3UA routes are in the one-to-one matching relation.
Name of the M3UA link set. The name of the M3UA signalling link set must be unique.
M3UA signaling link name. The M3UA link names and the M3UA links are in the one-to-one matching relation.
Name of the PCU
Whether to preferentially allocate loose multiplexing frequencies to non-AMR users
Filter consistent of the collision signal strength of power control. When sampling must be performed (NAVGI) times
before the MS obtains the efficient measurement signal.
Whether to enable the Tandem Free Operation (TFO) function on the BTS through a CHANNEL ACTIVATION or
MODE MODIFY message. This parameter specifies whether to enable the Tandem Free Operation (TFO) function. If
Uniform number of neighboring cell 1 index within a BSC6900, which uniquely identifies a cell and is in the range 0 to
5047.
Name of neighboring GSM cell 1
Index of neighboring GSM cell 2. Uniform number of a cell index within a BSC6900, which uniquely identifies a cell
and is in the range 0 to 5047.
Name of neighboring GSM cell 2
Uniform number of a cell index within a BSC6900
, which uniquely identifies a cell.
Name of a cell
Uniform number of a neighboring cell index within a BSC, which uniquely identifies a cell.
The value range of the index of a 3G external cell is 5048 to 8047.
Name of a neighboring cell
When this switch is on, it indicates that the data of the adjacent cell is generated automatically. When this switch is
off, it indicates that these data must be configured manually.
Cell ID of a neighboring cell
Local Area Code (LAC) of a neighboring cell
Mobile Country Code (MCC) of a neighboring cell
Mobile Network Code (MNC) of a neighboring cell
Whether the PCU of the cell supports the 64 neighboring cells.
This parameter determines the capability of reporting the number of the neighboring cells of the BSC in the NACC
Whether to involve the load of the target cell in the algorithm for NC2 cell reselection. If this parameter is set to
Support, the load of the target cell is involved in the algorithm for NC2 cell reselection.
Whether to support the network control 2 (NC2). The NC2 enables the network side to control the cell reselection for
the MS when the MS reports the measurement report of the local cell and the neighboring cell.When this parameter
Network color code that is provided by the telecom operator. The NCC is used to identify networks from area to area.
The NCC is unique nationwide.
Network color code. It is used to uniquely identify different public land mobile network (PLMN) of the adjacent
country.
A set of NCCs of the cells to be measured by the MS. This parameter is an information element (IE) in the system
information type 2 and 6 messages.
NCC bitmap of the measurement report sent by the MS. The MS reports only the NCC bitmap of the BSIC and the
cell measurement report that matches the bitmap.
For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured
values in several consecutive measurement reports. This parameter indicates the number of measurement reports
For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured
values in several consecutive measurement reports. This parameter indicates the number of measurement reports
Neighboring cell interference level threshold 0
Neighboring cell interference level threshold 1
Neighboring cell interference level threshold 2
Neighboring cell interference level threshold 3
Neighboring cell interference level threshold 4
Neighboring cell interference level threshold 5
Neighboring cell interference level threshold 6
Neighboring cell interference level threshold 7
Number of blocks occupied by the NCH in the group call service
Number of the start block occupied by the NCH in the group call service
Network control mode for cell reselection of the MS. There are three modes. NC0: normal MS control. The MS shall
perform autonomous cell re-selection. NC1: MS control with measurement reports. The MS shall send measurement
The DSP and OSP are in the associated mode or non associated mode.
IP address mask of the VLAN
Minimum interval between two consecutive emergency handovers performed by an MS. During this interval, no
emergency handover is allowed.
IP address of the next hop
Next hop
Next hop
IP address of the next hop
Network ID
Name of the file to be downloaded. The file name must be complete and does not contain a wildcard.
This parameter is related to the paging channel of the system. There are three network operation modes: network
operation mode I, network operation mode II, and network operation mode III. Network operation mode I is used
No Mains Supply Alarm Cabinet No.
No Mains Supply Alarm Port No.
No Mains Supply Alarm Slot No.
No Mains Supply Alarm Subrack No.
Lower limit of input voltage 1
Upper limit of input voltage 1
Lower limit of input voltage 2
Upper limit of input voltage 2
Lower limit of input voltage 3
Upper limit of input voltage 3
Lower limit of input voltage 4
Upper limit of input voltage 4
Lower limit of input voltage 5
Upper limit of input voltage 5
Lower limit of input voltage 6
Upper limit of input voltage 6
Whether to allow non-AMR voice F-H handover
Decides the offset of the current ATCB together with other two parameters: "F-H Ho Period" and period of triggering
a F-H handover, thus selecting target users for F-H handovers. ATCB offset = (Period of triggering a F-H handover /
When the ATCB value of non-AMR full rate voice is no smaller than this parameter, the condition for non-AMR F-H
handovers is met.
Decides the current path cost offset together with other two parameters: "F-H Ho Period" and period of triggering a F-
H handover, thus selecting target users for F-H handovers.
When the path loss value of non-AMR full rate voice is no larger than this parameter, the condition for non-AMR F-H
handovers is met.
Quality threshold for non-AMR F-H handovers. When the uplink receive quality and downlink receive quality of a user
are both smaller than this parameter, a F-H handover is triggered for the user.
When the load of a cell is no smaller than this threshold, non-AMR F-H handovers are triggered in the cell.
When the ATCB value of non-AMR half rate voice is no larger than this threshold, the condition for non-AMR H-F
handovers is met.
When the path loss value of non-AMR half rate voice is no smaller than this threshold, the condition for non-AMR H-
F handovers is met.
Whether to trigger non-AMR H-F handovers according to the uplink and downlink receive quality
Quality threshold for non-AMR H-F handovers. When the receive quality of a user is no smaller than this parameter,
the user meets the condition for H-F handovers.
When the load of a cell is no larger than this threshold, non-AMR H-F handovers are triggered in the cell.
Type of the adjacent node
Decisions of no-downlink measurement report handovers can be made only when the number of consecutive no-
downlink measurement reports in the current call is no larger than this parameter.
Whether to enable the no-downlink measurement report handover algorithm
When a certain number of no-downlink measurement reports are received consecutively and the uplink receive
quality is no smaller than this parameter, no-downlink measurement report emergency handovers are triggered. No-
Normal output capacity of the battery group in specific discharging conditions (such as discharge rate, temperature,
and final voltage). Generally, the parameter is based on 10-hour discharge rate.
Whether to enable the III power control algorithm for Non-AMR calls. If enabled, power control is performed on Non-
AMR calls.
Period when the cell is in the non-DRX state
When the ANT_A tributary antenna current abnormally check mode is set to Mode 3, the parameter ALD Current
Prompt Alarm is checked by periodical pulse. The periodical pulse consists of antenna over-current duration and
When the ANT_B tributary antenna current abnormally check mode is set to Mode 3, the parameter ALD Current
Prompt Alarm is checked by periodical pulse. The periodical pulse consists of antenna over-current duration and
Whether to allow the cell normal reselection. If this parameter is set to PERMIT and "NC2 Load Reselection Switch"
is set to Support, the load of the target cell is involved in the algorithm for NC2 cell reselection.
Normal work temperature threshold of the cabinet
Whether to discard paging messages without TMSIs and all-cell paging messages that considerably increase the
load on the BSC system
Maximum number of measurement periods in which there is no traffic. If the number of measurement periods in
which there is no traffic reaches this parameter, the BTS reports an alarm indicating that there is no traffic.
If the BTS works in fallback mode and uplink VGCS connection is idle for a period specified by this parameter, the
BTS disables the VGCS connection automatically. This parameter is valid only for user-originated VGCS calls and is
Number of TRACERT packets sent to each TTL
For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured
values in several consecutive measurement reports. This parameter indicates the number of enhanced
For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured
values in several consecutive measurement reports. This parameter indicates the number of enhanced
Network resource indication that specifies a CN node in the MSC pool
Identifies the mapping relation from the NRI to the SGSN uniquely with the operator name
Controls the values of the FDD_Indic0 field, the NR_OF_FDD_CELLS field, and the FDD_Cellinformation field in
2quater and MI when 3G neighboring cells with scrambling code 0 are present.
Identifies a unique NSE
The identifier of a network service entity (NSE).An NSE manages a group of NSVCs.
For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured
values in several consecutive measurement reports. This parameter indicates the number of measurement reports
Whether the cell is located in the south latitude or north latitude
NSVC ID, identifies a unique NSVC. This ID must be negotiated with the peer SGSN.
NSVC index, identifies a unique NSVC.
If the inlet temperature is between "High Temperature Critical Point" and "Low Temperature Critical Point" and the
difference between the inlet temperature and the ambient temperature reaches the value of this parameter, the
If the outlet temperature is between "High Temperature Critical Point" and "Low Temperature Critical Point" and the
difference between the outlet temperature and the inlet temperature reaches the value of this parameter, the
Number of retransmissions of the VGCS UPLINK GRANT message
Ratio of the minimum guarantee bandwidth of the OAM stream to the port bandwidth
Minimum guarantee bandwidth of the OAM stream
Minimum guarantee bandwidth of the OAM stream
Minimum guarantee bandwidth of the OAM stream
Ratio of the minimum guarantee bandwidth of the OAM stream to the port bandwidth
DSCP value of the OAM stream. The data of the OAM stream are not added to queues 0 to 5 for transmission.
Instead, the data of the OAM stream is added to the dedicated queue.
Minimum guarantee bandwidth switch of the OAM stream
Operation object
Type of the object
Index of object
This parameter indicates the object index.
Shield type of the alarm. "ALL" indicates one shield type instead of all types.
Type of the alarm shield object
Object index types used when commands are executed
When the PDCHs are insufficient, the streaming service with high priority can preempt the PDCHs that are seized by
the streaming service with low priority. After the PDCH resource preemption, the streaming service with low priority
Whether to allow overlay-to-underlay handovers
This parameter specifies whether to configure the backup OML. When YES is configured in the BTS, an OML is
configured in timeslot 31 of port 0 and port 1 respectively. The links are established on the two ports in turn after the
If OML Detection Switch is set to OFF, then the OML timeslot automatic detection is not supported. In this case, the
OML is carried on the default timeslots. If OML Detection Switch is set to ON, then the OML timeslot automatic
This parameter specifies the detecting time of Abis-Bypass site OML when it is broken.
Differentiated service code of the specified OML
The summation of average down-bandwidth of OML&ESL link in BTS.
The summation of average up-bandwidth of OML&ESL link in BTS.
Service priority of the specified OML
Priority of services on the OML. The operation and maintenance link (OML) is used to transfer the OM information
between the BSC6900 and BTS. This parameter indicates the priority of services on the OML.0 is the highest priority.
Specified OML Vlan Id
Size of the OML/ESL/EML Downlink LAPD window
External virtual IP address of the OMU
Subnet mask of the OMU in the external network
Account of the operator
Code of the original signaling point (OSP) in the signaling network. In the signaling network, each signaling point is
identified by a signaling point code.
Code of the signaling point of the local office in the signaling network. In the signaling network, each signaling point
has a corresponding signaling point code.
Uniquely identifies an OSP. see "ADD OPC" command.
Primary operator or secondary operator.
Primary operator is an operator that provides equipment, whereas secondary operator is an operator that leases
Index of the operator. This parameter uniquely identifies an operator.
Operator index set to which the CBC belongs
In the normal mode, if the board cannot be reset, no operation is performed. In the force mode, if the board cannot
be reset, the operation is performed by force.
It is one key filed of identifying A interface CIC status and indicates the alignment mode of A interface circuit.
It is one key filed of identifying Ater interface timeslot status and indicates the alignment mode of Ater interface
circuit.
It is one key filed of identifying A interface timeslot status and indicates the alignment mode of A interface circuit.
It is one key filed of identifying Pb interface CIC status and indicates the Pb interface CIC.
Name of the operator. This parameter uniquely identifies an operator
Channel assignment policies used when TCHs are assigned in an IUO cell: SysOpt: The system selects the
preferentially-assigned service layer and assigns channels according to the measurement reports on SDCCHs;
Preferentially assigns channels on the overlay when the uplink receive level on the SDCCH is no smaller than
"Assign-optimum-level Threshold" and the TA is smaller than "TA Threshold of Assignment Pref"; otherwise, assigns
Preferentially assigns channels on the overlay when the uplink receive level on the SDCCH is no smaller than
"Assign-optimum-level Threshold" and the TA is smaller than "TA Threshold of Assignment Pref"; otherwise, assigns
This parameter specifies the TRX priority in channel assignment. The smaller this parameter is, the higher the TRX
priority is. For two TRXs with other conditions identical, channels on the TRX with higher priority are preferentially
Optical interface standard
Type of the operation
The operation type can be "FORBID" or "RESTORE".
Iur-g signaling point index of an internal RNC in GU mode
If "Port Type" is set to "TOPEXTOUTPORT", this parameter determines the extended E1/T1 port through which the
timeslots on the source E1/T1 port are used by other boards. If "Port Type" is set to "TOPEXTINPORT", this
Operation type of the command.
Ordinary frequency. Multiple frequencies are separated by "&". For example, "22&33&44&55" are allocated to TRXs
in ascending order.
This parameter indicates the total number of hardware modules, excluding those of GSM.
One of the parameters that decide the underlay and overlay areas in an enhanced IUO cell. The underlay and
overlay areas are decided by "OtoU HO Received Level Threshold", "UtoO HO Received Level Threshold",
Whether to assign channel requests initiated in the underlay subcell to the overlay or underlay subcells according to
"UL Subcell General Overload Threshold". If the load of the underlay is higher than "UL Subcell General Overload
The timer is used to set the time when the BSC6900 waits for a handover success message after a handover
command is sent in an outgoing BSC handover. If the timer expires, the outgoing BSC handover fails.
The timer is used to set the time when the BSC6900 waits for an HO REQ ACK message after a Handover Request
message is reported in an outgoing BSC handover. If the timer expires, the outgoing BSC handover fails.
Whether to use external 2G neighboring cells as the target cells of load handovers
When the load of the underlay subcell is higher than this parameter, some of the calls in the underlay subcell will be
switched to the overlay subcell, and channels in the overlay subcell will be preferentially assigned to calls initiated in
Power overload threshold for triggering outgoing handover from the TRX under the prerequisite that the power
amplifier of the TRX provides the maximum output power. If the power overload exceeds this threshold, the TRX
Lower threshold of the overlay level during overlay-to-underlay handovers. When the receive level of an MS is higher
than this threshold, the MS can be switched to the underlay subcell.
Whether to switch some of the calls in the underlay subcell to the overlay when the load of the underlay is higher
than this parameter
If the underlay load is higher than "UL Subcell Serious Overload Threshold", the underlay-to-overlay handover period
subtracts a value that equals this threshold from "UL Subcell Load Hierarchical HO Periods" every second.
When the load of the underlay subcell exceeds "UL Subcell General Overload Threshold", all the calls that are using
this cell as the serving cell generate handover requests at the same time, which will suddenly increase the load of the
Level step during underlay-to-overlay hierarchical load handovers
When the load of the underlay subcell is lower than this parameter, some of the calls in the overlay subcell will be
switched to the underlay subcell, and channels in the underlay subcell will be preferentially assigned to channel
Specifies the timeslot mask out BSC6900
Outgoing BSC6900 port number
Number of the outgoing port of the DXX
Number of the outgoing timeslot of the DXX
Level of the accessed alarm signal. If the alarm signal has high level, this parameter should be set to 0. Otherwise, it
should be set to 1.
Level of the accessed alarm signal. If the alarm signal has high level, this parameter should be set to 0. Otherwise, it
should be set to 1.
Level of the accessed alarm signal. If the alarm signal has high level, this parameter should be set to 0. Otherwise, it
should be set to 1.
Level of the accessed alarm signal. If the alarm signal has high level, this parameter should be set to 0. Otherwise, it
should be set to 1.
Output power of the location group. For a location group that consists of MRRU or GRRU boards, the default output
power is 15W. For a location group that consists of DRRU boards, the default output power varies with frequency
Output power of the location group
Output power unit of the location group
When the load of the underlay subcell is higher than this parameter, the underlay-to-overlay load handover period
subtracts a period that equals "Step Length of UL Subcell Load HO" from "UL Subcell Load Hierarchical HO Periods"
Whether to report a cell out-of-service alarm after a cell is out of service
Outgoing BSC6900 slot number
Slot number of the load outlet interface board
Outgoing BSC6900 subrack number
This parameter specifies whether to allow the inter-RAT load handover in connection mode (after the assignment is
complete).
When the Service Handover field in an ASS REQ message is 0, a direct retry process targeted at a 3G network is
initiated. If the direct retry fails, the system decides whether to re-assign channels for the current call based on this
When this parameter is set to Open, the BSS decides whether to hand over the current service to the 3G network
according to the contents of the "Service Handover" information element in the ASS REQ and HO REQ messages.
Validity period for the BSC to keep the load information about a 3G neighboring cell on the RNC
Outgoing BSC6900 start timeslot number
Abnormally alarm raise threshold triggered by too heavy current of the ANT_A tributary antenna. When the actual
current is higher than the configured value, the ALD Current Abnormally Alarm is triggered with the corresponding
Abnormally alarm raise threshold triggered by too heavy current of the ANT_B tributary antenna. When the actual
current is higher than the configured value, the ALD Current Abnormally Alarm is triggered with the corresponding
Abnormally alarm raise threshold triggered by too heavy current of the RET tributary antenna. When the actual
current is higher than the configured value, the ALD Current Abnormally Alarm is triggered with the corresponding
Clearance threshold for the alarm triggered when the ANT_A tributary antenna is over current. When the actual
current is below this threshold, the ALD Current Abnormal Alarm is cleared.
Abnormally alarm clearance threshold triggered by too heavy current of the ANT_B tributary antenna. When the
actual current is lower than the configured value, the ALD Current Abnormally Alarm clearance is triggered with the
Clearance threshold for the alarm triggered when the RET tributary antenna is over current. When the actual current
is below this threshold, the ALD Current Abnormally Alarm is cleared.
When the ANT_A tributary antenna current abnormally check mode is set to Mode 3, the parameter ALD Current
Prompt Alarm is checked by periodical pulse. The periodical pulse consists of antenna over-current duration and
When the ANT_B tributary antenna current abnormally check mode is set to Mode 3, the parameter ALD Current
Prompt Alarm is checked by periodical pulse. The periodical pulse consists of antenna over-current duration and
Interval for the BTS transmitting overload messages to the BSC6900. This parameter is used to control the reporting
frequency of overload messages by the channel and TRX.
Temperature threshold of the derating function of the cabinet
Threshold for critical flow control. When the usage of the CPU exceeds the threshold, the CPUS performs critical
flow control for paging messages.
Threshold for major flow control. When the usage of the CPU exceeds the threshold, the CPUS performs major flow
control for paging messages.
Threshold for minor flow control. When the usage of the CPU exceeds the threshold, the CPUS performs minor flow
control for paging messages.
Threshold for slight flow control. When the usage of the CPU exceeds the threshold, the CPUS performs slight flow
control for paging messages.
This parameter specifies whether the multi-carrier transceiver unit supports the Multi-Carrier Intelligent Voltage
Regulation feature.
Whether to support the function of moving the packet assignment down to the BTS. To improve the access speed of
the MS, after the packet assignment is moved down to the BTS, the BSC reserves the uplink resources for the BTS.
Average number of paging messages allowed in a cell in a period
Lifetime of a paging message in the queue of the BTS. The setting of this parameter must be consistent with the
setting of timer T3113 in the core network; otherwise, the efficiency of paging scheduling over the Um interface is
Maximum number of paging messages allowed in a cell in a period
For the BTS, this parameter is used to determine paging retransmissions. This parameter and the number of paging
times configured in the MSC determine the number of paging retransmissions. The total number of paging times is
This parameter sets the PAN_DEC value used by the counter N3102 of the MS. When the timer T3182 of the MS
expires, the N3102 reduces the value of PAN_DEC. 0: the value of PAN_DEC is 0; 7: the value of PAN_DEC is 7;
This parameter sets the PAN_INC value used by the counter N3102 of the MS. When receiving the packet uplink
acknowledged or unacknowledged message sent by the network (V(S) or V(A) increases), the MS increases the
RAN_MAX value, the maximum value of the N3102. 4: the value of PAN_MAX is 4; 32: the value of PAN_MAX is 32.
Value N indicates that PAN_DEC is N; Not use: this parameter is not used.
Priority level at which the BSC shuts down the power amplifier of the TRX when the intelligent shutdown function is
enabled. If this parameter is set smaller, the priority level is higher, the power amplifier of the TRX is shut down later.
Patch number of the TMU board software
Patch number of the TMU board software
IP path check flag
Uniquely identifies an IP path
IP path ID,Identifying an IP path.
Transmission loss difference between radio frequencies on different bands
Whether to perform path loss-based sorting in a better cell handover algorithm
Type of the IP path
Patch type
BTS power attenuation on the measured PBCCH
Whether to use the PBGT handover algorithm. PBGT handovers are based on path loss. The PBGT handover
algorithm searches in real time for cells that have lower path loss and meet certain system requirements, and
The triggering of PBGT handovers must meet the P/N criteria, that is, when the condition for PBGT handovers is met
for a consecutive P seconds during N seconds, a PBGT handover is triggered. This parameter corresponds to the P
PBGT handovers to a neighboring cell are allowed only when the downlink level difference between the neighboring
cell and the serving cell is larger than this parameter. When the value of this parameter is smaller than 64,
The triggering of PBGT handovers must meet the P/N criteria, that is, when the condition for PBGT handovers is met
for a consecutive P seconds during N seconds, a PBGT handover is triggered. This parameter corresponds to the N
Maximum times for an external PCU to retransmit a PB interface maintenance message. When the PCU fails to
receive a response to a PB interface maintenance message before the timer timeouts, it retransmits the PB interface
Minimum interval between two consecutive power control commands
Channel used for the measured receiving power. It is used to set the measured receiving power level of the channel
and control the power of the uplink.
It is one key filed of identifying Pb interface CIC status and indicates the PCU No. corresponding to the Pb interface
CIC.
PCU number, identifying a unique PCU.
Port number of the E1/T1 of the Pb interface
Number of the PCU to which the current cell belongs
Whether the PCU supports the PREEMPT_ABIS_LINK message. If the BTS supports the FLEXABIS function, the
CS service can preempt the timeslots on the Abis interface used by the PS service. After the preemption occurs, the
PDCH downlink multiplex threshold, Indicating the maximum TBFs on the downlink PDCH (parameter value/10).We
recommand that the value of "Downlink Multiplex Threshold of Dynamic Channel Conversion" should be less than
This parameter specifies whether to enable the Power Optimization Based on Channel Type feature. The working
voltage of the TRX varies with the modulation mode of the channel. When this parameter is set to YES, the TRX
This parameter must be used together with "Level of Preempting Dynamic Channel" in the following conditions:
1. When "Level of Preempting Dynamic Channel" is set to "No preempt of service TCHF" and "PDCH Reforming" is
PDCH uplink multiplex threshold, indicating the maximum TBFs on the uplink PDCH (parameter value/10). We
recommand that the value of "Uplink Multiplex Threshold of Dynamic Channel Conversion" should be less than
Pending timer of the M3UA link set
Peer BSC ID. It identifies a BSC.
ID of the peer BSC6900
IP address of the peer BSC6900 on the homing BSC6900 side
Subnet mask of the port IP address at the peer BSC6900.
Identifier of the peer BTS on the homing BSC6900 side
Peer IP address of the PPP link. The IP address of the PPP link on the peer side of the BSC.
Peer IP address of the MP group.
Detects the IP address of the gateway
IP address of the peer end of BTS PPP Link.
IP address of the peer end of BTS MLPPP Group.
First destination IP address. The invalid value is 0.
Second destination IP address. The invalid value is 0.
The peer IP address should not be the same as the local address.
Subnet mask of the peer IP
Destination SCTP port number
Peer Software Version
Whether to punish the target cell when a handover fails or to punish the current serving cell when a handover is of
more TA or bad quality.
Penalty duration for cell reselection. Cell penalty can be performed only in this duration. When this parameter is set
to a greater value, the MS cannot reselect a cell for a longer time in the case of reselection failure or reselection due
When the cell reselection failure message is received or the load cell reselection is initiated, the "Cell Penalty Level"
is subtracted from the receive level of the target cell to avoid that cell reselection failure occurs repeatedly or that
Timer of penalty on a neighboring cell when a handover fails due to faults of data configuration.
Ping check period of IP Path
Measurement period for each frequency group
Compression flag of the PPP link protocol domain
Compression flag of the PPP link protocol domain
Whether to compress the protocol field of the PPP link.
Whether to support packet flow context (PFC). The PFC flow is used to control the QoS of the packet service of the
MS.
Whether to support the paging message classification function:
0,close;
Maximum number of paging messages that the BSC6900 can process over the A interface within a measurement
period
Maximum number of PS paging messages that the BSC6900 can process within a "Paging Statistical Period".
Measurement period for calculating the arrival rate of paging messages
Value of the per-hop behavior (PHB)
PHB type of the IPMUX to be enabled
Cell Reselect Parameters Indication (PI), sent on the broadcast channel, indicates whether "Cell Reselect Offset",
"Cell Reselect Temporary Offset" in the "SET GCELLIDLEAD" command, and "Cell Reselect Penalty Time" are
Whether to enable the private key password
DISABLE: indicating that the private key password is disabled
Indicates the number of the packets for remote loopback test of the OAM in the Ethernet
Indicates the length of the packets for the remote loopback test of the OAM in the Ethernet
Loopback packet length
Maximum multiplexing frame length. The length of the multiplexed packet must not exceed the maximum multiplexing
frame length. If the length of the multiplexed packet exceeds the maximum multiplexing frame length, the packet is
Whether the cell supports the PACKET SI STATUS flow. In the PACKET SI STATUS flow, the MS sends the Packet
PSI/SI Status message to indicate that the MS has stored the system message. The network side sends the Packet
Indicates the size of the PING packet, neither IP header nor ICMP header is included.
Sent packet size
Persistence level 1 of the radio access priority.
During MS access, the access priority of the MS is set. If the priority of the MS is higher than the access priority of
Power attenuation level of all the other timeslots of the BCCH except for timeslot 7 in 16QAM. The attenuation level
ranges from 0 to 50, with the step of 0.2 dB. When the EDGE TRX sends signals in 16QAM, the transmit power must
Persistence level 2 of the radio access priority.
During MS access, the access priority of the MS is set. If the priority of the MS is higher than the access priority of
Persistence level 3 of the radio access priority.
During MS access, the access priority of the MS is set. If the priority of the MS is higher than the access priority of
Power attenuation level of all the other timeslots of the BCCH except for timeslot 7 in 32QAM. The attenuation level
ranges from 0 to 50, with the step of 0.2 dB. When the EDGE TRX sends signals in 32QAM, the transmit power must
Persistence level 4 of the radio access priority.
During MS access, the access priority of the MS is set. If the priority of the MS is higher than the access priority of
Power attenuation level of the EDGE TRX. There are 50 power attenuation levels. At each level, the power is
attenuated by 0.2 dB. The spectrum requirements are met only when the power of an EDGE transceiver for
Statistics period of the packet drop ratio. This parameter indicates the period for collecting the statistics information
about the packet drop ratio. Note that the unit of this parameter is 100 milliseconds. The actual delay statistics period
Packet drop ratio threshold for speed reduction. When the packet drop ratio exceeds the value of this parameter, the
rate of the logical port is reduced. Note that the unit of this parameter is a thousand to one.
Point at which to play sound
Whether to enable sound playing
Duration of sound playing. If this parameter is set to 0, the sound is played repeatedly. If this parameter exceeds the
duration of the record file, the void sound is played for the exceeding part.
CPU usage threshold for performance monitoring. When the average CPU usage of sliding windows reaches or
exceeds the threshold, performance monitoring is triggered.
Packet queue usage threshold for performance monitoring. When the average packet queue usage of sliding
windows reaches or exceeds the threshold, performance monitoring is triggered.
Interval for sending cell paging group packets when Paging Messages Optimize at Abis Interface is enabled
Number of cell paging group packets when Paging Messages Optimize at Abis Interface is enabled
Whether to enable Paging Messages Optimize at Abis Interface. The BSC6900 combines multiple paging messages
to a cell paging package and then sends the package to the BTS. The package reduces header overhead and thus
CPU usage threshold for recovery from performance monitoring. When the average CPU usage of sliding windows is
lower than the threshold, performance monitoring is stopped.
Packet queue usage threshold for recovery from performance monitoring. When the packet queue usage of sliding
windows is lower than the threshold, performance monitoring is stopped.
Whether to monitor the RRM performance
Number of the port
Port No. of environment alarm
Port No. of the XPU board. If you do not specify this parameter, all ports of the XPU board are queried.
Number of the E1/T1 port on the Ater interface board. E1 mode: 0~31 (EIU), 0~62(OIU), 0~251(POUc). T1 mode:
0~31(EIU), 0~83(OIU), 0~335(POUc).
Port number
It is one key field of identifying the block of the Ater timeslot and indicates the port No. of the Ater interface timeslot.
Port number of the E1/T1 of the Pb interface
Number of the port where the alarm is generated, only the ports for data transmission are supported, such as E1/T1
port, channelized optical port tributary, optical port, and Ethernet port
Indicates the port number for running this command.
E1/T1 port number
E1/T1 port number
E1/T1 port number
Indicates the port number for running this command.
Port number
Port number
Port number
Ethernet port
FE/GE port number
Ethernet port
Port number
E1/T1 port number
Port number
Port number of Pb signaling link
Port No. of the BSC6900 board connected with the BTS
Alarm port number
Number of the port on the BTS side
Number of the port on the BTS side
Number of the port through which the BTS is connected to the BSC6900
Number of the FE or GE port
Number of the Ethernet port. The number must be consistent with that of the port carrying the FE connection of the
IP BTS.
Port number
Maximum transmission delay of the POC service (push to talk over cellular). The transmission delay of the POC
service must be relatively small. The network side must support the function of detecting the POC service type and
Maximum bandwidth of the POC service (push to talk over cellular). The transmission delay of the POC service must
be relatively small. The network side must support the function of detecting the POC service type and reduce the
Minimum bandwidth of the POC service (push to talk over cellular). The transmission delay of the POC service must
be relatively small. The network side must support the function of detecting the POC service type and reduce the
Whether to support the push to talk over cellular (POC) service
This parameter specifies a condition for generating a BTS alarm. When the output power of a TRX of a transmitter is
lower than a fixed level, an error is generated. This parameter and "Power output error threshold" indicate the two
This parameter specifies a condition for generating a BTS alarm. When the output power of a TRX of a transmitter is
lower than a fixed level, an error is generated. This parameter and "Power output reduction threshold" indicate the
Description of the rollback point
Name of the rollback point
This port is provided by the FTP server to be visited by the FTP client.
Number of the port where to set up the link after the BTS ring is swapped. If this parameter is set to 0, the BTS works
on a forward ring. If this parameter is set to 1, the BTS works on a backward ring.
Number of the port where to set up the link after the main and backup OMLs of the BTS are swapped
Number of the DXX port
Maximum number of ports on the DXX
Port protocol type
Whether to enable the panel port of the XPU board
Indicates the type of the physical port used by the local maintenance point in the maintenance group. FE indicates
the FE port and TRUNK indicates the aggregation group.
Type of the port. If this parameter is set to "TOPEXTOUTPORT", the local E1/T1 ports are used to extend the
transmission of other boards. That is, the timeslots on the source E1/T1 port are used by other boards through the
Whether to transmit the 2Quater message on the BCCH Norm channel or the BCCH Ext channel
Type of the patch operation
Rated maximum output power of the diesel engine. Refer to the rated output power described on the diesel engine
label.
Relay switch 1
Relay switch 2
Relay switch 3
Relay switch 4
Relay switch 5
Relay switch 6
Battery current shunt coefficient
Power attenuation level of timeslot 7 of the BCCH in 16QAM. The attenuation level ranges from 0 to 50, with the step
of 0.2 dB. When the EDGE TRX sends signals in 16QAM, the transmit power must be lower than the mean power in
Power attenuation level of timeslot 7 of the BCCH in 32QAM. The attenuation level ranges from 0 to 50, with the step
of 0.2 dB. When the EDGE TRX sends signals in 32QAM, the transmit power must be lower than the mean power in
Power type managed by the PMU
Type of the power supply system of the cabinet
This parameter specifies the transmit power level of the TRX. The greater this parameter is, the smaller the transmit
power is. When this parameter is set to "0", the transmit power level of the TRX is the greatest. Each time this
This parameter specifies the maximum transmit power supported by the power amplifier of the TRX. The macro BTS
and the mini BTS support different power levels.
When the number of error frames on the PPP layer reaches the value of this parameter, the frame error alarm is
generated.
When the number of error frames on the PPP layer decreases to the value of this parameter, the frame error alarm is
cleared.
PPP link number of BSC.
PPP link number
PPP link number
Number of a BTS PPP link.
Whether to enable the PPP frame multiplexing function. If this parameter is set to ENABLE, the PPP frame
multiplexing function is enabled. If this parameter is set to DISABLE, the PPP frame multiplexing function is disabled.
This parameter applies to the FG2a and GOUa boards. For the FG2c, GOUc, or POUc board, this parameter is
always set to 2.
This parameter specifies whether the preempted call is released after the handover failure. If this parameter is set to
No, MSs with high priorities can access the network preferentially, but the preempted call drops; if this parameter is
This parameter specifies whether to preempt PDCHs when no TCH is available during the handover of the
preempted call. When this parameter is set to Yes, the call drop rate of the preempted call is decreased, but the rate
If this parameter is set to ON, the BSC initiates a TCHF preemption when receiving a link establishment indication
from an MS in an emergency call.
Sampling rate of pre-processed measurement reports.
Priority of a route. A smaller value of this parameter indicates a higher priority. The BTS preferentially selects the
route with a high priority to transfer information.
Access priority of the MS that is allowed to access the cell. The MS sends the packet channel request containing the
2-bit radio priority message. The priority of the 2-bit radio priority message ranges from 1 to 4 in descending order.
This parameter specifies whether to support flow control based on priority. When this parameter is set to on, the
system preferentially admits the calls initiated by VIP users.
Whether the BTSs send the original measurement reports to the BSC after pre-processing them. When this
parameter is set to YES, the BTSs sends the original and pre-processed measurement reports to the BSC.
Printing control threshold. If the CPU usage of sliding windows reaches or exceeds the threshold, printing flow control
is triggered on the serial port.
Printing control threshold. When the packet queue usage of sliding windows reaches or exceeds the threshold,
printing flow control is triggered on the serial port.
Printing control threshold. If the CPU usage of sliding windows is lower than the threshold, printing flow control on the
serial port is stopped.
Printing control threshold. When the packet queue usage of sliding windows is lower than the threshold, printing flow
control on the serial port is stopped.
Whether to control the printing flow on the serial port
This parameter controls handover between cells at the same layer. Generally, the cells at the same layer are set with
the same priority. If the cells at the same layer have different priorities, a cell with a smaller priority value has a higher
This parameter controls the handovers among cells on a same layer. A smaller priority value indicates a higher
priority. Cells with higher priorities are preferentially selected as the handover target cells.
If the static Abis resource load is greater than the value of "Fix Abis Prior Choose Abis Load Thred" and the dynamic
Abis resource load is greater than the value of this parameter, the half-rate channel is preferred. Otherwise, the full-
Priority of the hierarchical cell structure (HCS).
0: indicates the lowest priority;
Route priority. The highest priority is represented by 0.
Priority of the signaling link. 0 indicates the highest priority. A low-priority link carries services only when the high-
priority link is faulty.
Route priority. The boards FG2a, GOUa, UOIa(IP), FG2c, and GOUc support the configuration of routes with
different priorities. Suppose two or more routes are configured and their addresses and masks are the same, and the
Preferential customized detection type when the customized sequence is used for port detection.
Number of customized detection types involved when the customized sequence is used for port detection.
Subsidiary customized detection type when the customized sequence is used for port detection. This parameter is
valid only when Number of Customized Detection Types is set to 2.
Name of the private key file
Port detection sequence used during BTS startup.
Identifies the DSP protocol type, including ITUT(International Telecommunication Union - Telecommunication
Standardization Sector), ANSI(American National Standards Institute), and TTC(Telecommunication Technology
Protocol type of the trunk frame. The setting of this parameter must be consistent with the setting at the SGSN side.
The transmission resource in the Abis timeslot is considered as faulty only when the BTS detects that the Abis
timeslot is faulty in the delay. The transmission resource in the Abis timeslot is considered as normal when the BTS
This parameter specifies a period of time during which a cell cannot be enabled or disabled to prevent frequent cell
enabling or disabling operations. That is, after a cell is enabled, it cannot be disabled within the period of time
This parameter is set to prevent the BSC from frequently enabling or disabling the TRX. After a TRX is powered on,
the BSC is not allowed to disable the TRX within the period of time specified by this parameter.
Port selection
Port selection
Port selection
This parameter indicates whether to include Abis interface messages in PS CHR logs.
This parameter indicates whether to include Gb interface messages in PS CHR logs.
This parameter indicates whether to include internal information in PS CHR logs. The internal information is the basic
user information, including user type, MS mulitple timeslot capability, cause for TBF abnormal release, and service
This parameter indicates whether to include internal messages in PS CHR logs. The messages are generated in
service data flow and transmitted between internal moudles, including uplink/downlink resource request,
This parameter indicates whether to include Um interface messages in PS CHR logs.
GSM PS data service downlink factor
GSM PS data service uplink factor
Whether to support PS Handover(PS HO). The PS HO is used to reduce the interval of the cell reselection of the
MS.
PS high PRI data path
PS high PRI data priority
Priority for PS services over the Abis interface in IP, IP over E1, or HDLC mode when PS preferred. When "Level of
Preempting Dynamic Channel" is set to "No preempt of service TCHF" through the "SET GCELLPSCHM" command,
Period for sending the packet message PSI. If the period is too long, the message PSI cannot be obtained in
realtime. If the period is too short, the message PSI is broadcast frequently, which occupies too much system
Whether the BSC supports the state message PSI. The state message PSI refers to PSI STATUS.
PS low PRI data path
PS low PRI data priority
Priority for PS services over the Abis interface in IP, IP over E1, or HDLC mode when CS preferred. When "Level of
Preempting Dynamic Channel" is set to "Preempt all dynamic TCHFs" or "No preempt of CCHs" through the "SET
Threshold of the receive level for triggering the handover of the PS services from the overlaid subcell to the underlaid
subcell
This parameter indicates the mode of exporting PS CHR logs. When the parameter is set to "Common User
Mode", the PS CHR logs of a specified cell are exported (the command is "SET GPSCHRSCOPE"); when the
This parameter specifies the level threshold for the random access of the MS. If the receive level of the RACH burst
in the PS domain is smaller than the value of PS RACH Min.Access Level, the BTS regards this access as an invalid
Minimum voltage level for accessing PS services of the location group
This parameter indicates whether to record PS CHR logs.
Maximum number of messages in the statistical period for the arrival of PS resource requests
Statistical period for the arrival of PS resource requests
Whether to enable the DPSU0 to supply power for the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether to enable the DPSU1 to supply power for the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether to enable the DPSU2 to supply power for the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether to enable the DPSU2 to supply power for the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether to enable the DPSU3 to supply power for the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether to enable the DPSU4 to supply power for the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether to enable the DPSU5 to supply power for the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether to enable the DPSU6 to supply power for the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether to enable the DPSU7 to supply power for the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Threshold of the receive level for triggering the handover of the PS services from the underlaid subcell to the overlaid
subcell
This parameter specifies whether the BTS is allowed to enable the PSU Smart Control feature.
When this parameter is set to YES, the BTS automatically enables or disables the PSU according to the traffic
Switch for the self-healing of the OMU processes
Port type of environment alarm
Number of the port that provides the time information on the SNTP server
Cell Reselect Penalty Time (PT) is used to ensure the safety and validity of cell reselection because it helps to avoid
frequent cell reselection. For details, see GSM Rec. 05.08 and 04.08.
Subnet protocol type
Alarm port type
Line coding method
Receiving frame structure
Sending frame structure
Frame structure
Number of a BTS HDLC path. It is unique in one [BTS].
Ethernet port type
Power system type. When the PMU is installed on the rack, you can select the custom power system type.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Name of the certificate file
This parameter specifies the patch version loaded to the BTS.
This parameter can be set to only a hot patch version. You can use either of the following methods to query the
Number of the patch version
Period timer of PVC utilization report. This timer is started during initialization. When the timer expires, the PVC
utilization information is reported.
Private key password
Password
User password for the FTP server. When the FTPServer.exe file downloaded through the LMT is installed, the user
password is admin.
Minimum length of the user password
Power level
First alarm switch of power distribution monitoring board
Second alarm switch of power distribution monitoring board
Whether to allow active power control. If this parameter is set to YES, the system performs power forecast in the
process of initial access assignment or service channel activation during intra-BSC handovers, and sends the
Whether to enable the optimized power control algorithm III
Whether to enable power control algorithm II or power control algorithm III
If a class 3 MS on the DCS1800 band does not receive the original power command after random access, the power
that the MS uses is the MS maximum transmit power level plus the power calculated from the power deviation. For
The MS does not receive the original power command after random access. This parameter indicates whether the
power deviation is added to the class 3 MS on the DCS1800 band on the basis of the maximum MS transmit power.
Whether to enable the power amplifier for all location groups. 0x01 indicates that the TRX power amplifier is enabled
for all location groups. 0x00 indicates that the TRX power amplifier is enabled for the current location group.
Power mode.
Time interval between the time when the BTS detects that the external power supply is shut down and the time when
the backup power decrease function is started. This parameter is valid in the BTSs that supports the backup power
When this parameter is set to YES, The BSC6900 preferentially uses the TRX with good power-saving performance
according to the TRX power priority reported by the BTS. Smaller priority value indicates better power saving quality.
Finetune of the TRX power. During the static finetune of the TRX power, the BSC adjusts the TRX power at a step of
0.2 dB. In some scenarios, the losses vary depending on the tributaries where the power is combined, and the power
When the ANT_A tributary antenna power switch is ON, it is allowed to configure related parameters of the ANT_A
tributary.
When the ANT_B tributary antenna power switch is ON, it is allowed to configure related parameters of the ANT_B
tributary.
When the RET tributary antenna power switch is ON, it is allowed to configure related parameters of the RET
tributary.
Minimum DSCP of queue 0. The IP packets with DSCP in a relation that "Min DSCP of queue 0" <= DSCP <= 63 is
added to queue 0.
Minimum DSCP of queue 1. The IP packets with DSCP in a relation that "Min DSCP of queue 1" <= DSCP < "Min
DSCP of queue 0" is added to queue 1.
Minimum DSCP of queue 2. The IP packets with DSCP in a relation that "Min DSCP of queue 2" <= DSCP < "Min
DSCP of queue 1" is added to queue 2.
Minimum DSCP of queue 3. The IP packets with DSCP in a relation that "Min DSCP of queue 3" <= DSCP < "Min
DSCP of queue 2" is added to queue 3.
Minimum DSCP of queue 4. The IP packets with DSCP in a relation that "Min DSCP of queue 4" <= DSCP < "Min
DSCP of queue 3" is added to queue 4. The IP packets with DSCP in a relation that 0 <= DSCP < "Min DSCP of
This parameter specifies the threshold of the signal level for cell reselection in connection mode before ""Qsearch
C"" is obtained.
Whether to enable the fast moving micro-cell handover algorithm. The fast moving micro-cell handover algorithm
enables fast moving MSs to switch over to macro-cells, thus reducing the handover times.
This parameter is used in the P/N criteria decision: If an MS quickly passes through N out of P micro-cells lately, the
BSC enables the fast moving micro-cell handover algorithm. This parameter corresponds to the N in the P/N criteria.
A time threshold determined based on the radius of a cell and the moving speed of an MS. If the MS crosses the cell
in a time period shorter than this threshold, the BSC concludes that the MS quickly passes through the cell.
This parameter is used in the P/N criteria decision: If an MS quickly passes through N out of P micro-cells lately, the
BSC enables the fast moving micro-cell handover algorithm. This parameter corresponds to the P in the P/N criteria.
This parameter specifies the level threshold for cell reselection in idle mode.
In idle mode, if the signal level of the serving cell is below [0, 7] or above [8, 15], the MS starts to search for 3G
For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured
values in several consecutive measurement reports. This parameter indicates the number of measurement reports
For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured
values in several consecutive measurement reports. This parameter indicates the number of measurement reports
Whether to support QoC optimization. The GSN equipment for the GPRS provides flexible QoS mechanisms for
different subscribers. The QoS level is also set during subscription. The QoS control parameters include: service
This parameter specifies one threshold of the signal level for cell reselection in packet transfer mode.
In packet transfer mode, if the signal level of the serving cell is below [0, 7] or above [8, 15], the MS starts to search
In connection mode, if the signal level is below [0-7] or above [8-15], the MS starts to search for 3G cells. For
example, if this parameter is set to 5 and if the signal level of the serving cell is lower than 5, the MS starts to search
This parameter is used to avoid allocating the calls whose signal strengths differ greatly to the same timeslot.
The BSC measures the signal merge conditions on each timeslot every 0.5 seconds. If the difference between the
The P/N criteria is used to determine low downlink power for multi-density carriers. If the downlink power of a multi-
density carrier remains low during a consecutive P seconds out of N seconds, the downlink power of the multi-
The P/N criteria is used to determine low downlink power for multi-density carriers. If the downlink power of a multi-
density carrier remains low during a consecutive P seconds out of N seconds, the downlink power of the multi-
Whether to use the statistical multiplexing algorithm for multi-density power
Maximum number of times that the BTS finds that the air conditioner needs to be switched off. If the number of times
that the BTS finds that the air conditioner needs to be switched off in the "CHKOFFTIMES" checks reaches this
Maximum number of times that the BTS finds that the air conditioner needs to be switched on. If the number of times
that the BTS finds that the air conditioner needs to be switched on in the "CHKONTIMES" checks reaches this
Step of downward power adjustment according to the quality of the received signals
Whether to query the classmark of the call in an incoming BSC handover
Whether to allow the fast handover algorithm
Auxiliary devices of rack 0. This parameter contains eight bits.
The eight bits, from the most significant bit to the least significant bit, indicate whether to install a voltage stabilizer,
Whether to configure a battery rack for rack 0
Capacity of the battery rack configured for rack 0
Ratio of the maximum charging current of the battery pack configured for rack 0 to the capacity of the battery pack.
For example, assume that the battery pack has a capacity of 200 AH. If this parameter is set to 0.15C, the maximum
Type of the battery rack configured for rack 0
Auxiliary devices of rack 1. This parameter contains eight bits.
The eight bits, from the most significant bit to the least significant bit, indicate whether to install a voltage stabilizer,
Whether to configure a battery rack for rack 1
Capacity of the battery rack configured for rack 1
Ratio of the maximum charging current of the battery pack configured for rack 1 to the capacity of the battery pack.
For example, assume that the battery pack has a capacity of 200 AH. If this parameter is set to 0.15C, the maximum
Type of the battery rack configured for rack 1
Auxiliary devices of rack 2. This parameter contains eight bits.
The eight bits, from the most significant bit to the least significant bit, indicate whether to install a voltage stabilizer,
Whether to configure a battery rack for rack 2
Capacity of the battery rack configured for rack 2
Ratio of the maximum charging current of the battery pack configured for rack 2 to the capacity of the battery pack.
For example, assume that the battery pack has a capacity of 200 AH. If this parameter is set to 0.15C, the maximum
Type of the battery rack configured for rack 2
The NS performs location management based on routing areas during GPRS packet services. Each routing area has
a routing area identifier, which is broadcast as a system message.
The NS performs location management based on routing areas during GPRS packet services. Each routing area has
a routing area identifier.
Identifies the routing area of the current cell
Route area of the current cell
Route area of the current cell
Route area of the current cell
This parameter specifies the level threshold for the random access of the MS. If the receive level of the RACH burst
in the CS domain is smaller than the value of CS RACH Min.Access Level, the BTS regards this access as an invalid
Level threshold of the MS random access for the BTS to determine the RACH busy state. When the receive level of
the random access burst timeslot is greater than this threshold, the BTS considers that the timeslot is busy.
Number of RACH burst timeslots in a RACH load measurement.
The value of this parameter indicates the interval during which the BSC6900 determines whether an RACH timeslot
Minimum voltage level for accessing CS services of the location group
Routing area color code of the GPRS cell
Whether to allow the MS to access another cell
Correlation threshold of the training sequence for the random access.
As defined in the GSM recommendation, the system can determine whether the received signals are random access
Hysteresis of cell selection in different routing area. When a standby or ready MS starts cell reselection, if the original
cell and the target cell are in the different routing area, the signal level of the neighboring cell must be greater that of
Port rate of the IP interface board
Switch for controlling the AMR rate. Value 0 indicates that C/I is used to control the AMR rate. Value 1 indicates that
BER is used to control the AMR rate.
This parameter specifies whether the RATSCCH function is enabled during the call establishment procedure.
RATSCCH is used to dynamically reconfigure the rate set of AMR while on a call. This parameter maps the versions
Original measurement report sampling rate (for each call, one out of four measurement reports is collected)
LASTRBP indicates the last rollback point. The system automatically takes the position where the current
configuration command is executed as the rollback point, and the user does not need to specify a rollback point.
Type of recording the execution result
1. REC_ALL: indicating that the execution results of all the commands are recorded no matter whether the
Number of the RXU chain or ring. The value scope is 0~11 for Non-SingleRAN BTS and 0~249 for SingleRAN BTS.
The RXU chain No. is unique in the same BTS. A maximum of 12 RXU chains can be configured in one BTS.
The first RXU chain number when combining two RXU chains to be one RXU ring.
The second RXU chain number when combining two RXU chains to be one RXU ring.
RF receive mode of the TRX.
The BTS3012, BTS3012AE, BTS3012II, BTS3006C, and BTS3002E do not support Main Diversity.
Speed reduction efficient of the logical port. When detecting link congestion through IPPM, the system reduces the
bandwidth rate of the logical port by using the value of the bandwidth multiplied by this parameter.
Whether to allow the reassignment function
Whether to re-assign the radio channels on a different band or on the same band. This can help minimize the
decrease in service quality due to interference, faulty TRX paths, or faulty project constructions.
IUO cell receive quality threshold (AMRFR), which is used for IUO handover decision
IUO cell receive quality threshold (AMRHR), which is used for IUO handover decision
One of the parameters that decide the underlay and overlay areas. The underlay and overlay areas are determined
by "RX_QUAL Threshold", "RX_LEV Threshold", "RX_LEV Hysteresis", "TA Threshold", and "TA Hysteresis"
One of the parameters that decide the underlay and overlay areas. The underlay and overlay areas are determined
by "RX_QUAL Threshold", "RX_LEV Threshold", "RX_LEV Hysteresis", "TA Threshold", and "TA Hysteresis"
Whether to use the downlink receive level as a condition in IUO handover decision
With traffic control enabled, the BSC discards some paging messages. This parameter specifies whether to record
detailed information of paging messages discarded by the BSC in the commissioning logs.
Speed reduction alarm recovery threshold
One of the parameters that decide the underlay and overlay areas.
If "Enhanced Concentric Allowed" is set to OFF, the underlay and overlay areas are determined by "RX_QUAL
Whether to use the downlink receive quality as a condition in IUO handover decision
Whether to back up the data of the board
Interval for releasing the secondary links in the congestion state
Secondary link bandwidth that is released each time in the congestion state
Port for output LINE2(The actual value range may differ on the LMT )
Back-up port for output LINE2(The actual value range may differ on the LMT )
Port for output LINE1(The actual value range may differ on the LMT )
Back-up port for output LINE(The actual value range may differ on the LMT )
Switch of panel BITS1(2M)
Switch of panel BITS2(2M)
Whether to use SGSN clock source.Only the Gb interface board needs to set this parameter. If the SGSN clock and
the MSC clock have different clock sources, the MSC clock must use the clock source of the SGSN clock. If the two
Region information of the IP BTS configured with local switching. Local switching can be performed between only the
BTSs that have the same region information.
Absolute time of re-homing
Delay time of re-homing
Policy type of re-homing
Whether to re-initialize the neighboring cell pair for software synchronization
Cabinet number of the associated module. The associated two MRFUs or GRFUs must be in the same cell.
Whether to enable the configuration of the "Extend Connection" attribute. The "Extend Connection" attribute
describes the cascading relationship of the DFCB, which helps the DFCU perform the six-in-one function.
Function to be performed by two associated modules
Slot number of the associated module
Subrack number of the associated module
Tributary Number of the DFCB that is cascaded to the DFCU. The "Extend Connection" attribute describes the
cascading relationship of the DFCB, which helps the DFCU perform the six-in-one function.
Remark
Purpose description of the route record
Remote NSVL ID of the Gb IP route
A key parameter that indicates how many times the BSC6900 broadcasts cell messages. You can obtain the cell
broadcast times by running the "DSP GSMSCB" command.
When the cell supports Repeated Downlink FACCH, the BTS enables the repeated transmission of FACCH frames if
the measured downlink quality is higher than "Repeated Downlink FACCH Threshold".
If the cell supports the Repeated Downlink FACCH function and the measured downlink quality is lower than the
downlink quality threshold, the BTS enables the repeated transmission of FACCH frames.
When the cell supports Repeated Downlink SACCH, the BTS enables the repeated transmission of SACCH frames if
the measured downlink quality is higher than the downlink quality threshold.
Whether to reserve the binding of the alarm ID and the alarm port
Whether to perform resource checks on the resource usage system and resource management system. Resource
checks can prevent resource hanging in case of anomalies. Resource checks cover channel resources, transmit
Indicating that during cell reselection, the level of the target cell should meet the following condition: Level of target
cell > [MAX (level of serving cell, "Cell Reselection Level Threshold") + "Cell Reselection Hysteresis"]. In this way,
NC2 cell reselection interval in the same cell
The number of received Packet Measurement Report messages on the receive level of the serving cell is measured
continuously. When the statistical value is greater than or equal to the value of this parameter, the normal reselection
If the number of times when the receive level of the serving cell within "Normal Cell Reselection Watch Period" is
lower than "Cell Reselection Level Threshold" is greater than the value of this parameter, the normal cell reselection
This parameter specifies the number of the reserved PDCHs that are not used for channel converstion in the
dynamic transferable channel pool.
This parameter specifies the number of idle channels that should be reserved on a cell after the TRX is shut down.
When the number of idle channels on a cell is smaller than this threshold, the BSC6900 enables a TRX. This
Whether to withhold link breakdown alarms in case of BTS resets due to data configurations
If OML links break down after BTS resets caused by data configurations and recover within the period specified by
this parameter, configuration reset alarms are reported;
Interval for resetting the counter when the user fails to log in
Retry times after the peer response timer expires during NSVC reset
The waiting time from BTS detect OML disconnect to BTS reset.
Duration of the peer response timer during NSVC reset
Reason for activating the radio status procedure
Whether the HO RQD messages sent by the BSC to an MSC carry response request cells. Response request cells
are optional. They are used to inform the MSC whether it needs to return HO REJECT messages when HO RQD
Whether to resume broken download
Duration of the PPP/MP link restart timer
Duration of the PPP/MP link restart timer
Restoration type of the alarm
Time for the BSC to initiate the common measurement or information exchange procedure after this procedure fails
While assigning channels, the BSC ensures that the sum of the number of channels occupied by high-priority users
and the number of idle channels reserved for high-priority users is no smaller than this parameter. Every time the
Maximum number of levels that the BTS RF power decreases. This parameter is used to control the decrease in the
BTS RF power. If the value is too large, the BTS power decreases too much. If the value is too small, the BTS power
Interval for sending the radio resource indication messages. The TRX reports the interference level for each of the
channels that have been idle for the whole measurement period.
Interval for executing the scheduled subtask
The unit is determined according to the time mode.
1. This parameter specifies whether to configure the DRFU, MRFU, GRFU, or XRFU by slot or link.
2. When setting the BTS to support the configuration of the RFU by slot, set this parameter to "YES". When setting
Satellite card protocol that is enabled to communicate with the satellite card connecting to the DGPS. If "RGPS" is
specified, it indicates that the RGPS satellite card protocol is enabled to communicate with the satellite card
Whether to support RAN information management (RIM). IN the RIM procedure, RANs(Radio Access Network) can
exchange messages through the core network.
The loopback channel number when the port loopback mode is set to TDM remote loopback
Time for disconnecting a call when the MS fails to decode the SACCH. Once a dedicated channel is assigned to the
MS, the counter S is enabled and the initial value is set to this parameter value.
Transmission mode on the Ater interface of the remote TC subrack. The meaning of values is as follows:
STANDALONETC: not converged
RNC ID of a 3G external cell. The value of this parameter must be consistent with the data configuration at the RNC.
Internal index of a neighboring RNC. This parameter is set to 255 when the neighboring RNC that serves the 3G
external neighbor is not configured. You can use the "LST GNRNC" command to check whether the neighboring
Internal index of a neighboring RNC
Name of a neighboring RNC. The name is used to uniquely identify a neighboring RNC.
Name of the root certificate file
Identifies a router uniquely
Router port number. The setting of this parameter must be consistent with the setting at the SGSN side.
Whether to allow the BTS to report the downlink voice quality index (VQI). The VQI is used to indicate voice quality. It
is calculated on the basis of BER, FER, and frame stealing.
Cell reselection measurement report period in packet idle mode
Cell reselection measurement report period in packet transmission mode
Speed reduction alarm report threshold
Whether to allow the BTS to report the voice quality index (VQI). If this parameter is set to Report, the BTS reports
the VQI. The BSC6900 collects the traffic statistics on a per VQI basis. There are 11 levels of speech quality. If the
For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured
values in several consecutive measurement reports. This parameter indicates the number of enhanced
For the purpose of accurately reflecting the radio environment of a network, filtering is performed on the measured
values in several consecutive measurement reports. This parameter indicates the number of enhanced
Resource group number of the PATH
The parameter indicates whether the resource group is shared or is used by a specific telecom carrier.
Resource management mode. The logical port working in the SHARE mode can be shared by multiple carriers. The
logical port working in the EXCLUSIVE mode can be used by only one carrier.
Timer for punishing the neighboring cells when handover failures occur due to resource-related causes, such as
resources being insufficient
This parameter adjusts "Min RSCP threshold" to enable the selection of 3G candidate cells based on cell priorities
This parameter determines the layers of 3G neighboring cells. If the measured value of a 3G neighboring cell is lower
than this threshold, the 3G neighboring cell is positioned at the bottom layer, that is, layer 4.
RSD alarm triggering source
RSF alarm triggering source
Used for calculating C2. The MS with a large value can be assigned with high access priority.
Average down-bandwidth of RSL link in BTS.
Differentiated service code of the specified RSL
RSL service priority
Average up-bandwidth of RSL link in BTS.
Specified RSL Vlan Id
Size of the RSL LAPD window
Reason for locking the configuration and management control rights
Threshold of the level difference between a neighboring cell and the serving cell, based on which the BSC filters the
measured values in the measurement reports and collects traffic statistics during automatic neighboring cell
This is the description file for resetting the board. The reset file names of different boards are different.
Name of the result file generated after the command is executed. If this parameter is not specified, the name of the
result file is automatically generated in the format of BATCH_RST_YYYYMMDDHHNNSSmmm. The result file is
Whether to enable the restart function
Timer
Maximum number of TCH channels reserved for emergency call users
Parameter 1 reserved for future use.
Parameter 10 reserved for future use.
Parameter 2 reserved for future use.
Parameter 3 reserved for future use.
Parameter 4 reserved for future use.
Parameter 5 reserved for future use.
Parameter 6 reserved for future use.
Parameter 7 reserved for future use.
Parameter 8 reserved for future use.
Parameter 9 reserved for future use.
Number of reserved idle channels. If this parameter is set too small, the TRX may be frequently enabled/disabled; if
this parameter is set too large, idle TRX will not be timely closed.
Recovery mode of the MSP protection group
Routing context. The routing context identifies a specified route. If the routing context is to be configured, its value
must be negotiated between the two ends.
Ratio of the RTCP path bandwidth to the A interface bandwidth. According to the Real-time Transport Control
Protocol (RTCP), the BSC6900 and the MSC negotiate the bandwidth occupation rate of the user plane on the A
Whether to enable the real-time transport control protocol (RTCP) function. The BSC6900 and the MSC negotiate
whether and how to compress the data over the A interface according to the RTCP. The setting of this parameter on
Destination IP address
Routing mask
Index of a route. The index is unique in a BTS.
It is used to calculate the round-trip time of the protocol stack and the RTO value. The value must be smaller than
"RTOBETA". In the case of the fixed value of the "RTOBETA", the larger the value is, the less the link delay
It is used to calculate the round-trip time of the protocol stack and the RTO value. The value must be greater than
"RTOALPHA". In the case of the fixed value of the "RTOALPHA", the larger the value is, the less the link delay
When the "RTOMIN" and "RTPMAX" parameters are set to fixed values, the larger the value is, the longer the check
of the link is.
When the "RTOMIN" parameter is set to a fixed value, the larger the value is, the longer the check of the link is.
When the "RTOMAX" parameter is set to a fixed value, the larger the value is, the longer the check of the link is.
Whether to measure the delay on the link between the BTSs that serve the calling MS and the called MS respectively
Maximum number of RTTI TBFs that can be multiplexed on the PDCH. A PDCH can be assigned when the number
of RTTI TBFs on it is smaller than the value of this parameter. This parameter is valid only when its value is smaller
Type of the route. When the BTS does not support IP over E1, the parameter Route Type needs to be set to
NEXTHOP(Next Hop). When the BTS supports IP over E1, the parameter Route Type needs to be set to OUTIF(Out
Logical port speed increase step. When detecting the available bandwidth increase through IPPM, the system
increases the bandwidth of the logical port by using this parameter.
Bandwidth increase step adjustment period. This parameter indicates the period to increase the bandwidth of the
logical port. Note that the actual bandwidth increase step adjustment period is the packet drop ratio Statistics period
R-version number of the BTS software
Receive bandwidth of IP path
Receive bandwidth
Minimum receiving power level for the MS in the cell to access the system
For AMR FR voice services, a fixed amount of offset is added to the corresponding grade of the received signal
quality for the interference handover of non-AMR FR voice services.
Minimum received signal level of the MS. This level is reported in the system information. This parameter specifies
the minimum receive level of an MS to access the BSS. For details. see GSM Rec. 05.08. The value of this
Whether to use the emergency handover algorithm in case the receive level of the MSs drops rapidly, thus
preventing call drops.
Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full
Rate.
Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full
Rate.
Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full
Rate.
Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full
Rate.
Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full
Rate.
Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full
Rate.
Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full
Rate.
Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full
Rate.
Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full
Rate.
Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full
Rate.
Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full
Rate.
Threshold for the interference handover of Non-AMR FR voice services. AMRFR refers to Adaptive Multi-Rate Full
Rate.
Number of the RXU chain to which the RXU belongs
Number of the RXU chain. The RXU chain No. is unique in one BTS.
Number of the RXU chain where the board is located
Index type of the RXU
Type of the RXU board index
Name of the RXU
Name of the RXU board. The RXU name is unique in one BTS.
Name of an RXU
Position number of the RXU on the RXU chain
Position No. of the RXU board on the RXU chain
Position of the RXU board on an RXU chain
Type of the RXU board
Whether to enable the switch to set the S1 value. S1 byte, also called the synchronization status byte, is one of the
optical connection parameters.
S1 sending value. It is a synchronization status byte used by the local end to examine the quality of the received
clock signals before the local end switches to a clock source with higher quality. The smaller the value of S1 is, the
Whether to enable the special analog alarm.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
The value of this parameter consists of 32 bits, each of which determines whether to enable the corresponding
special analog alarm. "0" indicates that the alarm is enabled, and "1" indicates that the alarm is disabled. When an
Whether the MSC independently processes the trunking services. When this parameter is set to YES, the MSC
independently processes the trunking services, that is, the trunking services are processed only by this MSC.
Whether an MS supports the SAIC function. Single Antenna Interference Cancellation (SAIC) is used to reduce the
impact of interference on the reception of downlink signals through a signal processing technology. An MS enabled
Adjustment step of the downlink signal quality threshold in power control algorithm II for MSs that support SAIC. The
network side uses a lower downlink signal quality threshold for SAIC-supported MSs in power control, thus lowering
Adjustment step of the downlink signal quality threshold in power control algorithm III for MSs that support SAIC. The
network side uses a lower downlink signal quality threshold for SAIC-supported MSs in power control, thus lowering
The value of this parameter consists of five bits, which determines whether to enable the alarms. "0" indicates that
the analog alarm is enabled, and "1" indicates that the analog alarm is disabled.
Index of a cell with the same coverage as the current cell
Index type used when the command is executed
The BSC6900 checks the load of the same coverage cell of the target cell once a minute. When the number of times
in which the load of the same coverage cell is lower than "Same Coverage Cell Load Threshold" is equal to the value
A cell that can be disabled is allowed to be disabled only when the load of the same coverage cell is lower than this
threshold for a period.
Name of the same coverage cell
This parameter is used by the BTS to inform the BSC6900 of radio link connection failure.
When the BTS receives the SACCH measurement report from the MS, the counter for determining whether a radio
The value of this parameter consists of three bits, which determines whether to enable the alarms. "0" indicates that
the alarm is enabled, and "1" indicates that the alarm is disabled.
Whether to enable the special alarm switch.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Level specifications of special Boolean value alarms. Two specifications are available: high level and low level. By
default, only alarms of the door status sensor are low level, and alarms of the water sensor, smoke sensor, and
Whether to enable the energy saving function of the TRX for the BTS3002E.
Whether to enable the special Boolean alarms, that is, water sensor alarm (bit 0), smog sensor alarm (bit 1), and
door sensor alarm (bit 2). All the Boolean alarms are enabled by default. "0" indicates that the alarm is enabled, and
Number of the BTS. The BTS is numbered uniquely in a BSC.
Name of the BTS. The BTS is named uniquely in a BSC.
This parameter indicates that when the MS reports the EMR, it adds the value of this parameter to the received
signal level, and then converts the result into the RXLEV value. For details, see GSM Rec. 05.08.
DSCP corresponding to the streaming service
When the network receives measurement reports, in consideration of the accuracy of a single measurement report,
the measurement values in certain measurement reports are filtered to represent the radio operating environment.
Number of the cell where the TRX reside. The cell is numbered uniquely in a BSC.
Name of cell 1
A key parameter that indicates the coding scheme of a simple cell broadcast message
Number of the sub-channel
Command string of the scheduled subtask. This command can be only a service command, and the system
command cannot be added to the scheduled subtask.
Type of querying used to set the measurement report collection scope.
Indicates the index of the inter-subrack connection path
Scrambling code of a 3G cell. The scrambling code is used to differentiate terminals or cells. It is used after spread
spectrum. Therefore, it does not change the bandwidth of signals, but only distinguishes the signals from different
Start serial number of the alarm record
SCTP link number of XPU board. This number identifies an SCTP link uniquely.
Date when the scheduled task is started
Start date of the alarm record. By default, the start date is 2000-01-01.
Start date of the alarm record. By default, the start date is 2000-01-01.
Maximum number of days for storing history alarms
SD alarm triggering threshold
Start date
Start date of the daylight saving time (DST)
Number of SDCCH channels. Rules for SDCCH channel allocation: 1. Allocate channels 1 and 3 of main frequency
B preferentially. 2. Allocate channels 1, 3, 5, and 7 according to the physical position order of the frequencies. Thus,
Whether a call must camp on the SDCCH for a specific duration before being assigned with a traffic channel.
Duration for a call camping on the SDCCH before being assigned with a traffic channel.
Level threshold for measuring the number of call drops on SDCCH. When call drop occurs on the SDCCH, the
BSC6900 determines whether the downlink receive level is lower than this threshold. If the downlink receive level is
Quality threshold for measuring the number of call drops on SDCCH. When call drop occurs on the SDCCH, the
BSC6900 determines whether the downlink quality level multiplied by 10 is higher than this threshold. If all the
Level threshold for measuring the number of call drops on SDCCH. When call drop occurs on the SDCCH, the
BSC6900 determines whether the uplink receive level is lower than this threshold. If the uplink receive level is lower
Quality threshold for measuring the number of call drops on SDCCH. When call drop occurs on the SDCCH, the
BSC6900 determines whether the uplink quality level multiplied by 10 is higher than this threshold. If all the following
Whether to allow SDCCH dynamic allocation, that is, whether to allow dynamic conversion between TCHs and
SDCCHs.
Enable SD
Whether to enable the SDCCH quick handover test function. If this parameter is set to Yes, the BSC6900 initiates
intra-cell SDCCH handover as soon as the MSC issues an encrypted command to the MS. Thus, the forwarding
This parameter specifies whether the BSC6900 automatically shuts down the power amplifier of the TRX to save
power when the BTS is powered by batteries after a power failure.
After a new SDCCH is assigned to an MS, the MS can be handed over to another channel only if the time during
which the MS occupies the SDCCH is longer than the period specified by this parameter.
Maximum number of discarded MRs allowed on the SDCCH in a power control period
Period in which level penalty is performed on the neighboring cells of the cell where a fast-moving MS is located. The
neighboring cells must be located at the Macro, Micro, or Pico layer other than the Umbrella layer.
Level value of the penalty that is performed on the neighboring cells of the cell where a fast-moving MS is located.
The neighboring cells must be located at the Macro, Micro, or Pico layer other than the Umbrella layer.
DSCP corresponding to the signaling
Specifies the SF and SD event priority
High temperature threshold for triggering power shutdown of the battery. If the power shutdown upon battery high
temperature is enabled and the battery temperature is higher than the value of this parameter, the battery is
Sliding time window for collecting statistics on the alarms that disappear in a specified period of time.Sampling time
window. In the period specified by this parameter, the duration in which the alarm persists is accumulated.
Sliding time window for collecting statistics on the alarms that occur in a specified period of time.This parameter is
similar to the sampling time window. In the period specified by this parameter, the duration in which the alarm
Low voltage threshold for triggering power shutdown of the battery. If the power shutdown upon low voltage is
enabled and the load voltage is lower than the value of this parameter, the battery is automatically powered off.
Whether to allow the MS to search for a 3G cell when the BSIC must be decoded
Self Software Version
This parameter specifies whether the SI Type 3 message contains the 2QUATER indicator.
Whether to report BSS INVOKE TRACE message. When the parameter is set to YES, the BSC sends a BSS
INVOKE TRACE message to the MSC if receiving an MSC INVOKE TRACE or BSS INVOKE TRACE message from
Whether to report the classmark queried by the BSC6900 to the MSC
Whether to send a CONFUSION message to the MSC. This parameter specifies whether to send a message
carrying fault location information to the MSC if the BSC receives a message that cannot be decoded over the A
If this parameter is set to No, the BSC responds with an SAPI N'Reject message against the DL short message after
hangup.
Priority of the notification message transmission on the FACCH. From high to low, the priorities are A, B, 0, 1, 2, 3, 4
and No Priority. No Priority is the lowest. When the priority of the group call is higher than or equal to the value
Priority of the paging message transmission on the FACCH. From high to low, the priorities are A, B, 0, 1, 2, 3, 4 and
No Priority. No Priority is the lowest. When the priority of the group call is higher than the value specified by this
The time for BTS reset.
Whether the BSC sends the System Information Type 2ter message.
Whether the BSC sends the System Information Type 5ter message.
Whether the SI Type 3 message contains the 3G Early Classmark Sending Restriction field. The 3G Early Classmark
Sending Restriction field is used to notify the MS of whether the early classmark message contains the 3G classmark
Split position on the RXU chain
Whether to enable the BTS to support the separation between the physical and logical. Whether the BTS supports
the separate mode. When a BTS is in separate mode, the physical boards are separate from the logical TRXs, that
Number of the command listening port of the server. You should not use any port number occupied by other
applications.
Number of the data port of the server in active mode. You should not use any port number occupied by other
applications.
Delivery serial number of the RET antenna
IP address of the FTP server to be visited by the FTP client
Service mode of the BSC6900. This parameter specifies configuration mode of subracks.
Service bearer mode of the BTS
Service bearer mode of the BTS
Name of the command function
Service type of the BTS. The QoS processing depends on the DSCP, VLAN ID, and VLAN priority that vary
according to the service type.
Whether to enable the diesel engine parameters to be configured
Whether to enable the environment temperature alarm parameters of the APMU to be configured. The APMU of the
APM30 type does not support this parameter.
Whether to enable the environment temperature parameters to be configured.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether to enable the environment humidity alarm parameters of the board to be configured.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Number of the SFP port. If the switching relation is added on the SFP port, it indicates that the SFP port is used to
connect the BBU and no RXU chain or ring can be configured on the port.
Available capacity of the SGSN
Name of the SGSN
Length of the NRI(Network Resource Identifier) or NULL-NRI. The length determines the maximum value of the NRI
and NULL-NRI.
Special NRI(Network Resource Identifier). Each SGSN pool has one NULL-NRI. When the NRI value in the TLLI of
the MS uplink/downlink service data equals NULL-NRI, the BSC6900 reselects an SGSN for the MS.
Whether to enable the SGSN pool function. With SGSN pool, a BSC6900 is connected to multiple SGSNs in the
pool, and load balancing and resource sharing between these SGSNs are allowed. In this manner, the PS services
Protocol version supported by the SGSN
Administrative state of the SGSN. The value "ALLOW" indicates that the SGSN can handle the PS services
normally. The value "UNISTALL" indicates that the SGSN does not permit new PS services to access the network
Usage threshold of the CPU for call access from other CPU. If the usage of the CPU exceeds the threshold, the call
access request is discarded.
Slot number of the load sharing interface board
Whether to allow sharing
Shield flag of the alarm
This parameter specifies the delay time before shutting down the TRXs when the BTS experiences a power failure.
Whether the BSC sends a System Information Type 2ter message to a non-dualband cell. When the parameter is set
to YES, the cell does not send the System Information Type 2ter message if the cell is not configured with inter-
Whether to enable a handover between signaling channels
Number of times that the downlink signal strength exceeds the threshold
Uniquely identifies a signaling link set
Uniquely identifies a signaling link set
ID of an M3UA link in the specified link set
Signaling local weight over the local NSVL. When this parameter is set to a larger value, the NS is more likely to
select this IP point according to the load sharing function of the NSVC link of the IP network, if the NS sends a
Signaling local weight over the remote NSVL. When this parameter is set to a larger value, the NS is more likely to
select this IP point according to the load sharing function of the NSVC link of the IP network, if the NS sends a
Priority of the signaling service.0 is the highest priority.
Number of times that the downlink signal is measured
Number of measurement reports used for averaging the signal quality of signaling channels. This parameter helps
avoid sharp drop of signal levels caused by Raileigh fading and to ensure correct handover decisions.
ID of an MTP3 link in a specified link set
Number of measurement reports used for averaging the signal strength of signaling channels. This parameter helps
avoid sharp drop of signal levels caused by Raileigh fading and to ensure correct handover decisions.
Minimum interval between the successful TBF establishment and the first initiation of the Packet Timeslot
Reconfiguration procedure
Single pass exclude MSISDN number 1. One-way audio means that only one party in a call can hear the voice.
Certain numbers, such as the premium rate number, are not used for the single pass check. The number is stored in
Single pass exclude MSISDN number 10. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 11. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 12. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 13. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 14. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 15. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 16. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 17. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 18. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 19. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 2. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 20. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 3. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 4. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 5. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 6. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 7. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 8. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Single pass exclude MSISDN number 9. Certain numbers, such as the premium rate number, are not used for the
single pass check. The number is stored in character string.
Source IP address
Source IP address
Log of which site need to be collected.
Zone where the BTS synchronizes with other BTSs. Only two BTSs with the same synchronization zone can be
synchronized in a synchronization task.
The IP address must be a valid class A, B, or C address, and it cannot be a broadcast address or network address.
No. of the location group under the BTS. The location group No. is unique for each BTS.
Self-loop type. The precautions are as follows:
1. If the self-loop type is set to "E1SELFLOOP" and the BTS type is BTS3002C, BTS3001C, or BTS3001CP, the
Signaling route load sharing. In the value, the number of 1s (represented by n) determines the maximum number (2)
of routes for the load sharing. For example, B0000 indicates that up to one route is used for the load sharing, B0001
If no handshake message is received from the peer within the delay, the slave service is activated. A slave service
object provides services at the peer BSC and its configuration data is backed up at the local BSC. A slave service
Type of the start date. "WEEK" indicates that the start date is a weekday. "DATE" indicates that the start date is a
month day. "DATEWEEK" indicates the start date is expressed by a combination of weekday and month day.
Index of the SMLC
Whether the built-in SMLC or external SMLC is used in the BSS.
Smog alarm switch
Month in which DST starts
Number of CPU usage samples involved in the calculation of the average CPU usage in the sliding window
Number of the slot
Number of the slot
Number of the slot where the XPU board is located
Number of the slot where the XPU board is located
Number of the slot
A key field used to identify the Ater timeslot and indicate the number of the Ater interface timeslot
Number of the slot
Number of the slot where the alarm is generated
Number of the slot where the alarm is generated, the number of the slot where the OMU board is positioned is not
supported
Indicates the slot number for running this command
Slot number for running this command
Number of the slot. The subrack number and slot number uniquely identify a board.
Slot No. of the subsystem where the Iur-g common connection is established
Number of the slot where the BTS board is located
Number of the slot where the BTS board is located
Slot number of the XPU board bound to the NSE
Slot number of board to which Pb signaling link belongs
Number of the slot where the port is located
Slot number of the BSC6900 board that is connected to the BTS
Number of the slot where the BTS board is located.
RF send mode of the TRX.
The BTS3006C and BTS3002E do not support Wide Band Combining, Power Booster Technology, DPBT, or
The connection mode between the DRRU and the antenna.
The connection mode between the DRFU and the antenna.
The connection mode between the MRRU/GRRU and the antenna.
The connection mode between the MRFU/GRFU and the antenna.
The connection mode between the BTS3900E and the antenna.
Synchronization period of the SNTP client service
As an integer, the OSP code can be expressed by a decimal digit or a hexadecimal digit. If the OSP code is
expressed by a hexadecimal digit, H' is added before the number.
Number of bits contained in the signaling point code
OSP code expressed in the form of segments 8-8-8, see the parameter "Signal point data format" of the "ADD OPC"
Start CIC of the E1/T1 of the Pb interface
Data format of the specified signaling point.
When this parameter is set to "WNF", the SPC is expressed in the form of an integer number.
This parameter is used for load control. It determines whether the users of special access class are allowed to
access the network. Value 1 indicates that access is not allowed. Value 0 indicates that access is allowed.
The value of this parameter consists of seven bits. Each bit determines whether to enable the one-way Boolean
alarm. "0" indicates that the one-way Boolean alarm is enabled, and "1" indicates that the one-way Boolean alarm is
The value of this parameter consists of five bits. Each bit determines whether the one-way Boolean alarm is triggered
by low level or high level. "0" indicates that the alarm is triggered by high level, and "1" indicates that the alarm is
If the number of one-way mute events exceeds the value of "Speech Channel Alarm Threshold" within this period,
then the BSC reports the Speech Channel alarm.
Whether to contain the information element of Speech_Ver in the Assignment Complete message
Whether to contain the information element of Speech_Ver in the Handover Perform message
Whether to contain the information element of Speech_Ver in the HO_REQ_ACK message
Whether to contain the information element of Speech Ver in the HO_RQD message
Speech version mode that the BTS uses for the VGCS call number in the timeslot in the TRX in fallback mode
Speech version mode that the BTS uses for the VGCS call number in the timeslot in the TRX in fallback mode
Speech version configured on the TRX timeslot when the BTS works in fallback mode. When "CHNTYPE" of the
TRX timeslot is set to "FULLTCH", value 0 of this parameter indicates FR and value 1 indicates EFR; when
Rate over the GE electrical port. When this parameter is set to 1000M, the GE electrical port performs negotiation at
the rate of 1000 Mbit/s. If, however, the negotiation result is not 1000 Mbit/s, the negotiation fails. When this
Level value of the penalty that is performed on the neighboring cells of the cell where a fast-moving MS is located.
The neighboring cells must be located at the Macro, Micro, or Pico layer other than the Umbrella layer.
Period in which penalty is performed on the neighboring cells of the cell where a fast-moving MS is located. The
neighboring cells must be located at the Macro, Micro, or Pico layer but not the Umbrella layer.
Whether to support SPLIT_PG_CYCLE on CCCH. The parameter SPLIT_PG_CYCLE is used to define the DRX
period. You can specify whether the paging group based on SPLIT_PG_CYCLE is supported on CCCH for the BTS
This parameter specifies whether the BSC6900 supports the cell broadcast function and whether the BSC6900
supports simple cell broadcast or standard cell broadcast.
Whether to support the common bidirectional measurement procedure on the Iur-g interface.
Whether to support the bidirectional information exchange procedure on the Iur-g interface.
Whether to support In Inter-RAT Inter-cell PS Handover. The MS in the UMTS cell can be handed over to the BSC
local cell through PS handover algorithm.
Whether support Out Inter-RAT Inter-Cell PS Handover. The MS in the BSC local cell can be handed over to the
UMTS cell through PS handover algorithm.
Whether the function of Network Assisted Cell Change (NACC) resource guarantee is allowed. In NC2 or NACC cell
reselection, if this parameter is set to YES, dynamic channels are requested in the target cell.
Whether the BSC forwards the paging message from the trunking MSC to the MS. When this parameter is set to
YES, the BSC forwards the paging message from the trunking MSC to the MS and forwards the corresponding
Whether to enable the layer 3 check mechanism on the LAPD links. If the PCU_BSC_LAPD_CHECK_ACK message
cannot be received on one Pb link, the Pb link is in single pass mode. Send another two
Whether to enable the enhanced resource check on the Pb interface.
The introduction of enhanced resource check is to improve the efficiency of resource checking and define the
Whether to enable the single pass check function on the Pb links between the BSC and the external PCU. When the
Pb link is in single pass mode, a corresponding alarm is reported to the maintenance terminal, and the Pb link is set
Whether to enable the PCIC check function on the Pb links between the BSC and the external PCU. When the
configuration of the PCIC of the BSC is inconsistent with that of the external PCU, a corresponding alarm is reported
Whether to support RAN Sharing.RAN sharing refers to the technique that the GBSS equipment is categorized into
multiple logical GBSS equipment, thus operators can share the GBSS equipment to cover the same area.
Cell supports reduced latency capability. This parameter is used to reduce the latency during the transmission, thus
improving the user experience for conversational services.
whether the main operator enables the RanSharing function. If the RanSharing function is enabled, one to three co-
operators can be configured to share the BSS.
Whether the FTP client supports the state firewall
Uniquely identifies an OSP
Whether a base station supports normalized data configuration. Normalized data configuration means that the
cabinets, subracks, slots, transmission ports, and user-defined alarm ports of a base station under a multi-mode BSC
Whether the data configuration of the SingleRAN BTS supports normalized SingleRAN mode. Normalized
SingleRAN mode means that the rules of defining cabinet number, subrack number, and slot number of the
Whether the data configuration of the SingleRAN BTS supports normalized SingleRAN mode. Normalized
SingleRAN mode means that the rules of defining cabinet number, subrack number, and slot number of the
A cell Index must be unique in one BSC6900
. It is used to uniquely identify a cell.
Name of a cell
A source cell index must be unique in one BSC. It is used to uniquely identify a source cell.
The value of this parameter ranges from 0 to 2047.
Name of a source cell
Source cell ID
The batch file to be executed: The content of the batch file consists of service commands to be executed in batches.
The source file is located in the FTP subdirectory of the OMU installation directory, and you should not add the path
Priority of the clock source
Priority of the clock source. There are four priorities (in descending order): 1, 2, 3, 4.
Whether the currently used handover algorithm in the source cell is HO Algorithm I or HO Algorithm II
Source IP address of BFD Session.
Local area code (LAC) of the source cell
Mobile country code (MCC) of the source cell
Identifies a maintenance point in the maintenance group
Mobile network code (MNC) of the source cell
Source of timeslot cross
Type of the clock source.
Source timeslot mask
Number of the subrack
Number of the subrack
Number of the subrack where the XPU board is located
Number of the subrack
Number of the subrack
It is one key field of identifying the Ater timeslot and indicates the subrack No. of the Ater interface timeslot.
Number of the subrack
Number of the subrack where the indicator alarm to be queried is generated
The subrack number for running this command
The subrack number uniquely identifies a subrack.
Subrack No. of the subsystem where the Iur-g common connection is established
Number of the subrack where the BTS board is located
Number of the subrack where the BTS board is located
Subrack number of the XPU board bound to the NSE
Subrack number of board to which Pb signaling link belongs
Number of the subrack where the port is located
Subrack number of the BSC6900 board that is connected to the BTS
Number of the subrack where the BTS board is located
Number of the subrack at one end of the inter-subrack connection channel
Number of the subrack at the other end of the inter-subrack connection channel
Name of the subrack to be added
Number of the tributary
Type of the subrack
Sequence of alarm records
Traffic local weight over the local NSVL. When this parameter is set to a large value, the NS is more likely to select
this IP point according to the load sharing function of the NSVC link of the IP network, if the NS sends a data
Traffic local weight over the remote NSVL. When this parameter is set to a larger value, the NS is more likely to
select this IP point according to the load sharing function of the NSVC link of the IP network, if the NS sends a data
The parameter specifies which type of service TRXs should be preferentially processed when the PSU is faulty.
Service type of the IP interface board. The service type can be CS speech, CS data, PS high priority, or PS low
priority.
After a handover due to bad quality is successful, the penalty on the original serving cell is performed within the
"Penalty Time after BQ HO": the receive level of the original serving cell is decreased by "Penalty Level after BQ
CPU usage alarm clearance threshold
CPU usage alarm threshold. When the CPU usage exceeds the threshold, a CPU usage alarm is reported. "CPU
occupancy alarm clearance threshold" is smaller than "CPU occupancy alarm threshold".
DSP usage alarm clearance threshold. When the DSP usage is lower than the threshold, the DSP usage alarm is
cleared.
DSP usage alarm threshold. When the DSP usage exceeds the threshold, a DSP usage alarm is reported. "DSP
occupancy alarm clearance threshold" is smaller than "DSP occupancy alarm threshold".
When the network receives measurement reports, the measurement values in several straight measurement reports
are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number
When the network receives measurement reports, the measurement values in several straight measurement reports
are filtered to reflect the radio operating environment for the sake of accuracy. The parameter specifies the number
Number of the subsystem
No. of the subsystem where the Iur-g common connection is established
Start synchronization number of the alarm record
After the time advancing handover is successful, the penalty on the original serving cell is performed within the
"Penalty Time after TA HO": the receive level of the original serving cell is decreased by "Penalty Level after TA HO",
Start of DST
The operation time of the log record should be after this time. If this parameter is not specified, the start time is not
limited.
If the time mode is set to "DAILY_T", "WEEKLY_T", or "MONTHLY_T", you should set this parameter.
The operation time of the log record should be after this time. If this parameter is not specified, the start time is not
limited.
Start time of the alarm record. By default, the start time is 00:00:00.
Start time of the alarm record. By default, the start time is 00:00:00.
A key parameter that indicates the date and time when the BSC6900 broadcasts cell messages
Start number of the alarm record
Whether to preferentially use the variable bitmap code when encoding the frequency in the System Information and
encoding the FH frequency in the assignment or handover command
This parameter indicates whether the arrival of channel request messages is controlled.
It indicates the start CIC of the A interface CIC segment. When operation mode is set to OPC index, DPC group
index, BSC ID, or CIC, the parameter is mandatory.
It indicates the start CIC of the Pb interface CIC segment. If the search object mode is set to search by the specified
range, the parameter is mandatory.
This parameter specifies the start date of a period during which the TRX Intelligent Shutdown feature is disabled.
When the environment temperature reaches the specified value of this parameter, the heater is started.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
This parameter specifies the start month of a period during which the TRX Intelligent Shutdown feature is disabled.
This parameter indicates whether the arrival of paging messages are controlled.
This parameter indicates whether the arrival of PS resource request messages is controlled.
Number of the start sub-timeslot
Time for which the BTS waits to start the fallback function after the OML is interrupted. With this parameter, the BTS
does not start the fallback function when the OML is interrupted transiently.
This parameter specifies the start time for dynamically enabling the TRX Intelligent Shutdown feature each day.
It indicates the start CIC of the Ater interface CIC segment.
It indicates the start CIC of the A interface CIC segment. When Operation mode is set to subrack number, slot
number, port number, or CIC, the parameter is mandatory.
Number of the start timeslot
Whether to enable the smart temperature control mechanism of the FMUA. Smart temperature control refers to the
mechanism adopted by the FMUA to adjust the fan speed, and thus to regulate the temperature according to the
Whether to enable the smart temperature control mechanism of the NFCB. Smart temperature control refers to the
mechanism adopted by the NFCB to adjust the fan speed, and thus to regulate the temperature according to the
Number of the start CIC. The C/C of each E1/T1 timeslot can be calculated on the basis of this parameter. Assume
that the start CIC is 100, the CIC of the E1 timeslots on the A interface will automatically be set to 100, 101, 102,
Number of the cabinet where the outgoing port of the BTS is located
Start date. The input format is YYYY&MM&DD.
Number of frequencies measured in each group (excluding the frequencies in the original BA table).
Satellite flag
Start time
Whether to enable the EICC algorithm. Enhanced Interference Rejection Combining combines the signals received
by multiple antennas to obtain better signals. EICC is mainly used in high traffic network where tight frequency reuse
This parameter specifies whether the sending of system information 5, 5bis, and 5ter can be stopped on the SACCH
on the SDCCH after the BTS issues a ciphering command.
Time for which the BTS waits to stop the fallback function after the OML is set up. With this parameter, the BTS does
not stop the fallback function when the OML is set up transiently.
Whether to enable the signaling point with the signaling transfer function
Number of the outgoing port of the BTS where the monitoring timeslot is located
Start time of frequency scanning
Number of the slot where the outgoing port of the BTS is located
Number of the subrack where the outgoing port of the BTS is located
Number of the sub-timeslot on the outgoing port of the BTS
Start time. The input format is HH&MM&SS.
Number of the timeslot on the outgoing port of the BTS
Type of the BTS.
ID of the BSC in the TC pool where an A interface circuit is blocked or unblocked
ID of the BSC in the TC pool to which an A interface E1/T1 is added
Command string that is transparently transmitted to the BTS
Maximum sub-frame length. This parameter indicates the maximum sub-frame length for multiplexing. If the length of
a sub-frame exceeds this value, the sub-frame is not multiplexed.
Maximum sub-frame length. The data stream to be multiplexed on the same multiplexing channel must be of the
same type, and the length of the packet before multiplexing cannot exceed the maximum subframe length. If the
Number of the scheduled subtask
Subnet Number in a BSC
This parameter specifies whether the CS services preempt the sublink resources of PS services.
Whether to allow the CS services to preempt the sublink resources of PS services when the Abis resources are
congested
Number of the sub-timeslot on the port
Sub-version No. of the TMU board. It is configured according to the actual situation.
Whether the CIC circuits in use on the A interface can be assigned. When this parameter is set to YES and the MSC
assigns new calls to an ongoing A interface circuit, the original calls (that are occupying the circuit) are released, and
Whether to use Back-up port for LINE2
Whether to use Back-up port for LINE1
Whether to support the broadcast of the cell name
Whether to support the high multislot class. High multislot class function enables a single MS to be allocated with a
maximum of five timeslots on the uplink or downlink, thus improving the uplink or downlink throughput of a single MS.
Whether to support dual transfer mode (DTM). The DTM allows an MS to use the circuit switching service and the
packet switching service at the same time. This function must be supported by the network side.
Whether to support EDA. Extended dynamic allocation (EDA) enables the MS to be allocated with more timeslots on
the uplink, thus improving the uplink rate and helping to transmit large amounts of data on the uplink.
Whether to support the enhanced DTM function. Comparing to the DTM, the enhanced DTM improves the CS setup
and release. During the CS service setup, the PS service is not interrupted.
Whether the FE/GE BTS supports inter-BTS local switching
Support intracell handover to change the active speech version, then can increase the usage of TFO(Tandem Free
Operation) to improve the speech quality.
Whether to support the cell list in the common measurement messages over the Iur-g interface. When this parameter
is set to YES, the local BSC can handle the load information of the cells in the cell list carried in the received
Minimum timeslots between two successive channel requests. After sending the access request, if the MS does not
receive the response message after waiting for the minimum timeslots between two successive channel requests,
Server IP address used on the SGSN side in the IP subnet dynamic configuration procedure
Server UDP port number used on the SGSN side in the IP subnet dynamic configuration procedure
Operating state of the environment alarm port
If this parameter is set to "ON", you must set "OMU automatic switchover interval". Otherwise, "OMU automatic
switchover interval" is not displayed.
Switch for authenticating objects. When the switch is enabled, the BSC system authenticates the BTS objects of the
user; when the switch is disabled, the BSC system does not authenticate the BTS objects.
Whether to enable the alarm port
Power switch state.
Weekday on which DST starts
State of the panel port switch
Switch for the OMU self-healing
Grace Protection Period Switch determines whether to enter the grace protection period.
Turn on or turn off the BFD protocol switch
Whether to enable the board parameters to be configured. If this parameter is set to "YES", the user can set board
parameters of the BTS. Otherwise, the user cannot set the board parameters.
Whether to enable the 3ah function on the BTS port.
The field indicates whether the primary path can be switched back when it is available.
The association is smoothly switched over to the primary path after the number of heartbeat responses is received.
Set patch switch parameter1
Set patch switch parameter10
Set patch switch parameter2
Set patch switch parameter3
Set patch switch parameter4
Set patch switch parameter5
Set patch switch parameter6
Set patch switch parameter7
Set patch switch parameter8
Set patch switch parameter9
Number of the switching port. If "Link Attribute" is set to "BBU", the switching port must be configured. The value
ranges from 3 to 5.
Whether to enable the local user management function
Sequence of the start week of DST
Symbol offset of the BTS set manually. After the offset information of the BTS is collected, the symbol offset is
adjusted. Adjustment value = Collected symbol offset relative to the reference BTS - (BTS symbol offset + BSC
Synchronization status. This parameter is used to identify different 3G cells. This parameter should be same with the
configuration of 3G cells.
Site synchronization method. AISS stands for the air-interface soft synchronization method, and GPS stands for the
GPS synchronization method.
Synchronization mode of the IP clock
Interim synchronization period (in days). The BTS can re-initiate the synchronization only after the period.
Interim synchronization period (in hours). The BTS can re-initiate the synchronization only after the period.
Interim synchronization period (in minutes). The BTS can re-initiate the synchronization only after the period.
Contact way of the Base Station Controller supplier
Description of the Base Station Controller
System flux thresholds correspond to the system flux obtained based on message packets, CPU load, and FID
queuing load. The system flux level is the current flux control level of the system.
Location of the Base Station Controller
Whether sending the system information type 10 message on the VGCS/VBS TCH is allowed. For detailed
information, see the 3GPP TS 44.018 9.1.50.
Name of the Base Station Controller of Network Element
Services provided by the Base Station Controller
Timer T1, specifying the duration of monitoring the BVC blocking (unblocking) procedure.
Value of the first timer for the PTU handshake
When the reception of a TFP causes unavailability of a route, this timer is started to regularly check whether the
route is recovered.
This timer is a protection timer waiting for an uninhibit acknowledgement message (LUA) from the peer end after an
uninhibit message (LUN) is sent to the peer end.
This timer is a protection timer waiting for a force uninhibit acknowledgement message (LUA) from the peer end after
a force uninhibit message (LFU) is sent to the peer end.
This timer is a protection timer waiting for an inhibition acknowledgement message (LIA) from the peer end after an
inhibition message (LIN) is sent to the peer end.
This timer is started when a link fails to be started. The restart of the link is initiated after this timer expires.
When a normal changeover cannot be initiated, services will be changed over to an alternative link after this timer
expires to avoid disorder of data.
Timer T2, specifying the duration of monitoring the procedure of resetting SIG BVC and PTP BVC.
Value of the second timer for the PTU handshake
Timer in the LAPD protocol. The value of the timer indicates the time when the LAPD link waits for the response or
acknowledgement frame after sending the command frame.
This parameter specifies the expiry value of timer T200 used for the FACCH/TCHF over the Um interface. For the
function of timer T200 and the effect of the parameter, see the description of "T200 SDCCH".
This parameter specifies the expiry value of timer T200 used for the FACCH/TCHH over the Um interface. For the
function of timer T200 and the effect of the parameter, see the description of "T200 SDCCH".
This parameter specifies the expiry value of timer T200 used for the SACCH over the Um interface when the TCH
supports SAPI3 services. For the function of timer T200 and the effect of the parameter, see the description of "T200
This parameter specifies the expiry value of timer T200 used for the SACCH on the SDCCH.
For the function of timer T200 and the effect of the parameter, see the description of "T200 SDCCH".
This parameter specifies the expiry value of timer T200 used for the SACCH over the Um interface when the TCH
supports SAPI0 services. For the function of timer T200 and the effect of the parameter, see the description of "T200
This parameter specifies the timeout value of timer T200 used for the SDCCH over the Um interface.
T200 prevents the data link layer from deadlock during data transmission. The data link layer transforms the physical
This parameter specifies the expiry value of timer T200 when the SDCCH supports SAPI3 services.
For the function of timer T200 and the effect of the parameter, see the description of "T200 SDCCH".
Timer in the LAPD protocol. The value of the timer indicates the maximum duration for no frame exchange in the
LAPD link.
After a local link is inhibited, this timer is started to regularly check the management states at both ends of the link.
After a remote link is inhibited, this timer is started to regularly check the management states at both ends of the link.
This timer is a protection timer waiting for an extended changeover acknowledgement message (XCA) from the peer
end after an extended changeover order message (XCO) is sent to the peer end.
Timer T3. T3 is started after the message SUSPEND is received on the BSC side. T3 is stopped after the message
SUSPEND ACK is received.
Value of the third timer for the PTU handshake
When the BTS sends physical information to the MS, the BTS starts the timer T3105.If the timer T3105 expires
before the BTS receives the SAMB frame from MS, the BTS resends physical information to the MS and restarts the
Timer for retransmitting the VGCS UPLINK GRANT message
T3168 is used to set the maximum duration for the MS to wait for the uplink assignment message. After the MS
originates the uplink TBF setup request by sending the packet resource request or the channel request in the packet
Duration of releasing the TBF after the MS receives the last data block. When the MS receives the RLC data block
containing the flag identifying the last data block and confirms that all the RLC data blocks in the TBF are received,
This parameter specifies the length of the timer for periodic location update.
Timer on the DTE side, specifying the duration of acknowledging the sending BC link integrity.
When a normal changeback cannot be initiated, services will be changed back to a normal link only after this timer
expires to avoid disorder of data.
Timer T4. T3 is started after the message v is received on the BSC side. T4 is stopped after the message RESUME
ACK is received.
This timer is a protection timer waiting for a changeback acknowledgement message (CBA) from the peer end after
the first changeback declaration (CBD) is sent to the peer end.
Timer T5. When the downlink TBF is set up, if the BSC side does not receive the valid RACAP, the BSC originates
the radio access capability update flow and the timer T5 is started. After receiving the core network response, the
This timer is a protection timer waiting for a changeback acknowledgement message (CBA) from the peer end after
the second changeback declaration (CBD) is sent to the peer end.
Timer T6. The BSC sends the SGSN request to download the BSS PFC. When the QoS parameter is obtained, the
timer is started. After the message CREATE_BSS_PFC is received, the timer is stopped. After the timer expires, the
Timer T8. The BSC sends the SGSN request to download the BSS PFC. When the QoS parameter is obtained, the
timer is started. After the message MODIFY_BSS_PFC_ACK is received, the timer is stopped. After the timer
This timer is started when a transmission prohibited message (TFP) is sent. The TFP will not be sent any more
during the running of this timer.
When the network receives measurement reports, the measurement values in several straight measurement reports
are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number
Whether the TA is used as a decisive condition for the concentric cell handover
Whether to enable the time advance (TA) handover. The TA handover determines whether the timing advance (TA)
is higher than the predefined TA threshold. When the TA is higher than the predefined TA threshold, a TA handover
One of the parameters that determine the coverage of the OL subcell and UL subcell.
When "Enhanced Concentric Allowed" is set to OFF, "TA Hysteresis", "RX_LEV Threshold", "RX_LEV Hysteresis",
The P/N criterion must be met for triggering a TA handover. That is, the TA handover can be triggered only if P
measurement reports among N measurement reports meet the triggering conditions. This parameter corresponds to
An emergency handover is triggered when TA is greater than or equal to the value of this parameter.
This parameter specifies the interval of broadcasting the speech data of the talker on the downlink group call channel
that is controlled by the BTS. When the parameter is set to 0, the BTS (instead of the BSC6900) performs the
When the network receives measurement reports, the measurement values in several straight measurement reports
are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number
Unique identifier of the Um interface software synchronization task
The P/N criterion must be met for triggering a TA handover. That is, the TA handover can be triggered only if P
measurement reports among N measurement reports meet the triggering conditions. This parameter corresponds to
One of the parameters that determine the coverage of the OL subcell and UL subcell.
When "Enhanced Concentric Allowed" is set to OFF, "TA Hysteresis", "RX_LEV Threshold", "RX_LEV Hysteresis",
Filter period of the signal strength in the packet transmission mode of the MS. The MS in the packet transmission
mode measures the downlink signal strength. This parameter is used to calculate the Cn value of the MS output
Filter period of the signal strength in the packet idle mode of the MS. The MS in the packet idle mode measures the
downlink signal strength. This parameter is used to calculate the Cn value of the MS output power. This parameter
Number of the output segment
1: Segment 1 describes the basic information of the equipment.
Output Segment No.
1: Segment 1 describes the basic information of the equipment.
Maximum time in which the BTS attempts to set up the OML after swapping the main and backup OMLs. If the BTS
fails to set up the OML within this time, the BTS swaps the main and backup OMLs again.
The BTS repeatedly attempts to connect to port 0 or port 1 after the switchover. If the connection on one port fails
within the time specified by this parameter, the BTS tries to connect to another port.
Test code for the MTP3 link. After the successful test, the link can be used for carrying signaling services. If the test
fails, the MTP3 periodically sends the fault locating command until the operation is successful. When the link is
Timer Tc, specifying the interval for the BVC and MS to send flow control messages. When this parameter is set to a
smaller value, the BVC and the MS send flow control messages in a shorter time, which allows the SGSN can use
Temperature compensation coefficient. This parameter defines the charging voltage increase or decrease unit of
each battery when the ambient temperature of the battery varies with the reference temperature regulated by the
This parameter specifies the cyclic redundancy check (CRC) switch, which can be set to On or Off. The value of this
parameter determines whether check is performed on the TRAU frame between the BSC6900 and the BTS.
Whether to allow the cell to dynamically change a channel from full rate to half rate or from half rate to full rate. If this
parameter is set to YES, the conversion is allowed; if the parameter is set to NO, the conversion is not allowed and
If the current channel seizure ratio reaches or exceeds this value, the half-rate TCH is assigned preferentially;
otherwise, the full-rate TCH is assigned preferentially.
When a call drops on the TCH, the corresponding TCH call drop counter is incremented by one if the DL FER carried
in the last MR is greater than the value of this parameter.
When a call drops on the TCH, the corresponding TCH call drop counter is incremented by one if the downlink level
carried in the last MR is lower than the value of this parameter.
When a call drops on the TCH, the corresponding TCH call drop counter is incremented by one if the downlink
quality carried in the last MR is greater than the value of this parameter.
When a call drops on the TCH, the corresponding TCH call drop counter is incremented by one if the UL FER carried
in the last MR is greater than the value of this parameter.
When a call drops on the TCH, the corresponding TCH call drop counter is incremented by one if the uplink level
carried in the last MR is lower than the value of this parameter.
When a call drops on the TCH, the corresponding TCH call drop counter is incremented by one if the uplink quality
carried in the last MR is greater than the value of this parameter.
After a new TCH is assigned to an MS, the MS can be handed over to another channel only if the time during which
the MS occupies the TCH is longer than the period specified by this parameter.
Maximum number of discarded MRs allowed on the TCH in a power control period
Whether the TCH rate type uses the MSC strategy or BSC strategy. When this parameter is set to NO and the MSC
policy is used, the BSC preferentially selects full-rate or half-rate channels based on the rate type carried by the MSC
This parameter specifies the interval at which the speech service on a TCH is handed over.
This parameter specifies whether to perform periodic intra-cell handover for speech services on TCH.
Threshold for determining that the underlaid subcell is busy. The BSC assigns channels in the underlaid subcell to
the MS in a concentric cell. When "Allow Rate Selection Based on Overlaid/Underlaid Subcell Load" is set to YES,
The BSC assigns channels in the overlaid subcell to the MS in a concentric cell. If the channel seizure ratio of
overlaid subcell is greater than the value of this parameter, half-rate channels are assigned. Otherwise, full-rate
Test code length of the signaling link. By default, the value is 10.
Mode of TC.
SEPERATE_PRINCIPAL: Specifies that the MTP3 link is configured for the primary BSC in the case of BM/TC
Whether to enable the class-1 mute detection.
Number of the cabinet where the main board of the RXU ring is located
Number of the TC port where one end of the ATER connection channel is located
If you enable the TC pool function when configuring the basic information of the BSC6900, you need to enter the TC
Pool ID. The ID must be unique in the entire network.
Number of the TC slot where one end of the ATER connection channel is located
Number of the TC subrack where one end of the ATER connection channel is located
The type of TC resource
GTC: TC resources that support normal voice coding/decoding and packet conversion
Input mode of the BA table. In auto mode, the system fills in the BA1 and BA2 tables based on the adjacent relation
of cells. In manual mode, the user maintains the BA table. If the adjacent relation of cells is modified, for example, a
Whether the FDD BA2 table is generated automatically according to the neighboring relation or typed manually.
When the priority of a TDD cell is ranked, the value of this parameter is added to the receive level of the TDD cell in
the measurement report.
A TDD cell can become a candidate cell only when the average receive level of the TDD cell is greater than the TDD
Cell Reselect Diversity of the serving cell.
Threshold for determining whether the MR about a TDD cell is valid.
The measurement report is valid if the receive level of the TDD cell in the measurement report is greater than the
This parameter specifies whether to activate the diversity mode on the common channel of a 3G cell.
Downlink frequency of frequency 1 in table 3GBA2. This parameter indicates the detected downlink frequency in the
3G adjacent cell list in speech. The parameter is delivered in the system information 2QUTER/MI.
This parameter specifies whether the TDD MI system information optimized function is enabled. When this
parameter is set to NO and "TDD System Information Optimized Allowed" is set to YES, the MI system information
This parameter specifies whether to send the system information MI which contains the 3G neighboring cell
information in the TDD neighboring cell. The value YES(YES) indicates that the MI is sent, and the value NO(NO)
Minimum RSCP quality threshold that the TDD 3G candidate cell must reach
TDD cell parameter ID. The ID is used to distinguish terminals or cells. This parameter is used after spread
spectrum. Therefore, it does not change the bandwidth of signals, but only distinguishes the signals from different
Cell parameter ID of a TDD cell. The cell parameter ID distinguishes between MSs or cells. It is used after spread
spectrum. Therefore, it distinguishes between the signals from different sources, but not the changes in the
This parameter specifies whether to optimize the system information 2Quater and MI of the TDD neighboring cell.
That is, to add an FDD neighboring cell information before the TDD neighboring cell information to solve the
SyncCase in the TDDBA1 table. This parameter determines the synchronization status. Value 0 indicates Sync case
1 and value 1 indicates Sync case 2. This parameter is used to identify different 3G cells.
If the ratio of available TDM bandwidth is greater than this value, congestion control is stopped.
If the ratio of available TDM bandwidth is less than or equal to this value, congestion control is triggered.
Each subrack has six TDM port numbers, ranging from 0 to 5. Subrack 1 TDM Port No. refers to the TDM port
number on subrack 1 of the inter-subrack connection..
Each subrack has six TDM numbers, ranging from 0 to 5. Subrack 2 TDM Port No. refers to the TDM number on
subrack 2 of the inter-subrack connection.
Terminal endpoint ID of the Pb signaling link
Temperature alarm switch
Upper limit of temperature
Lower limit of temperature
When the environment temperature of the APMU is greater than the value of this parameter, the BTS reports an
alarm. For the APMU of the non-EPS4815 type, the minimum value of the parameter is -490.
When the environment temperature is greater than the value of this parameter, the BTS reports an alarm.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
When the environment temperature of the APMU is less than the value of this parameter, the BTS reports an alarm.
For the APMU of the non-EPS4815 type, the maximum value of the parameter is 990.
When the environment temperature is less than the value of this parameter, the BTS reports an alarm.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Change value of the floating charge voltage of the storage battery when the temperature of the storage battery
changes by 1 degree Celsius.
Description of a cell template.
This parameter specifies the index number of a cell template. Each template is numbered uniquely in a BSC6900.
This parameter specifies the index number of a cell template. Each template is numbered uniquely in a BSC6900.
Name of a cell template, uniquely identifying a cell template in a BSC6900.
When the temperature of the BTS cabinet is greater than the value of this parameter, the TRX is powered off.
TRX power-off temperature threshold. If the temperature of the BTS cabinet is less than the value of this parameter
while "Low Temperature Startup Allowed" is set to "Yes", the TRX is powered off.
TRX power-off temperature threshold. If the temperature of the BTS cabinet is less than the value of this parameter
while "Low Temperature Startup Allowed" is set to "Yes", the TRX is powered off.
Whether the System Information Type 3 message carries TER indication.
Duration of the timer for starting the IP path status test on the Gb interface
Content of the cell broadcast message
AEC is an important measure to improve the speech quality. If the AEC works for a consecutive time that is longer
than the value of this parameter, the TFO function is closed to provide a better speech quality.
In the VSWR test, the TRX transmits signals at a default frequency. You can specify the frequency used for the test.
This parameter indicates start frame number of the BTS. It is used to keep synchronization between the BTS and MS
after the BTS is re-initialized.
Target OMU
TGW ID
This parameter indicates the address of the operation and maintenance console for TGW.
This parameter indicates the mask of the operation and maintenance console for TGW.
Slot number of the BSC6900 interface board interworking with TGW.
Subrack number of the BSC6900 interface board interworking with TGW.
Timer Th. After receiving the MS flow control message, the SGSN uses the values of the updated Bmax and R
based on the interval set by this timer. When this parameter is set to a smaller value, the SGSN can use the flow
Voltage threshold for switching off the air conditioner. If the power supply voltage is less than this threshold, the air
conditioner needs to be switched off to decrease the impact on the BTS.
Voltage threshold for switching on the air conditioner. This parameter assumes that the air conditioner is switched off.
If the power supply voltage is greater than this threshold, the air conditioner needs to be switched on to ensure that
Combination of the THP1 and ARP1 priority in the Interactive service. THP1-ARP1 priority weight determines the
number of the budget blocks and the block scheduling priority.
Combination of the THP1 and ARP2 priority in the Interactive service. THP1-ARP2 priority weight determines the
number of the budget blocks and the block scheduling priority.
Combination of the THP1 and ARP3 priority in the Interactive service. THP1-ARP3 priority weight determines the
number of the budget blocks and the block scheduling priority.
Combination of the THP2 and ARP1 priority in the Interactive service. THP2-ARP1 priority weight determines the
number of the budget blocks and the block scheduling priority.
Combination of the THP2 and ARP2 priority in the Interactive service. THP2-ARP2 priority weight determines the
number of the budget blocks and the block scheduling priority.
Combination of the THP2 and ARP3 priority in the Interactive service. THP2-ARP3 priority weight determines the
number of the budget blocks and the block scheduling priority.
Combination of the THP3 and ARP1 priority in the Interactive service. THP3-ARP1 priority weight determines the
number of the budget blocks and the block scheduling priority.
Combination of the THP3 and ARP2 priority in the Interactive service. THP3-ARP2 priority weight determines the
number of the budget blocks and the block scheduling priority.
Combination of the THP3 and ARP3 priority in the Interactive service. THP3-ARP3 priority weight determines the
number of the budget blocks and the block scheduling priority.
Load balance threshold type. It indicates the threshold calculation mode.
This parameter specifies the timer set to wait for a private message from the SGSN.
During channel assignment, the assignment of channels on the BCCH TRXs depends on the uplink receive level,
quality, and non-BCCH load. The TCHs are preferentially assigned on the BCCH TRXs if the following conditions are
During channel assignment, the assignment of channels on the BCCH TRXs depends on the uplink receive level,
quality, and non-BCCH load. The TCHs are preferentially assigned on the BCCH TRXs if the following conditions are
The P/N criterion must be met for triggering a TIGHT BCCH handover. That is, the TIGHT BCCH handover can be
triggered only if P seconds among N seconds meet the triggering conditions. This parameter corresponds to P in the
During channel assignment, the assignment of channels on the BCCH TRXs depends on the uplink receive level,
quality, and non-BCCH load. The TCHs are preferentially assigned on the BCCH TRXs if the following conditions are
The P/N criterion must be met for triggering a TIGHTBCCH handover. That is, the TIGHTBCCH handover can be
triggered only if P seconds among N seconds meet the triggering conditions. This parameter corresponds to N in the
When an intra-cell TIGHT BCCH handover needs to be performed (handover from the non-BCCH to BCCH), the
downlink receive quality must be smaller than the value of this parameter.
Whether to enable the BCCH aggressive frequency reuse algorithm
If the SDCCH load on the TRXs of the compatible BCCH in loose frequency reuse pattern is greater than the "IBCA
Loose Trx SDCCH Load Threshold", and when the uplink receive level from the MS to the BTS is greater than the
IMSI paging timer. After enabling the MSC pool function, the BSC6900 receives from the MSC the paging message
attached with the IMSI. Then, the BSC6900 records the relation between the IMSI and the MSC SP and starts the
Whether to limit the operation time of the operator
Time
Duration of frequency scanning
Within the preset time, no AMR FR-to-HR handover is allowed if the previous FR-to-HR handover fails due to
channel unavailability or channel mismatch.
After a handover due to bad quality is successful, the penalty on the original serving cell is performed within the
"Penalty Time after BQ HO": the receive level of the original serving cell is decreased by "Penalty Level after BQ
After an OL subcell to UL subcell handover of an MS fails, the MS does not perform OL subell-UL subcell handovers
within the value of the parameter.
Indicates the timeout time of the PING packet
Timeout time for waiting for the TRACERT packet response
Timeout time
Indicates the timeout time of the CFM link tracing detection
Longest waiting time for multiplexing
When the multiplexed packet is no longer added with new data and the timer expires, the multiplexed packet is
After the fast handover is successful, the penalty on the original serving cell is performed within the "Quick handover
punish time": the receive level of the original serving cell is decreased by "Quick handover punish value", to prevent
Indicates the times of sending PING packets
This parameter determines whether the dynamic voltage adjustment function is enabled on the basis of the number
of timeslots. If this parameter is set to YES, the power consumption of base stations is reduced. This parameter
After the time advancing handover is successful, the penalty on the original serving cell is performed within the
"Penalty Time after TA HO": the receive level of the original serving cell is decreased by "Penalty Level after TA HO",
After an UL subcell to OL subcell handover of an MS fails, the MS does not perform UL subcell to OL subcell
handovers within the value of the parameter.
This parameter indicates the queue timer for assignment.
When the BSC6900 receives an assignment request and no channel is available for assignment, the BSC6900 starts
If the BSC6900 receives the configuration data about all the connected MSCs before the timer expires, the BSC6900
concludes that the configuration data is valid.
When the operation time of the OMU exceeds the value specified by this parameter, some records are deleted from
the operation log.
Temporary logical link ID in the decimal format
Lowest expected value of the air outlet temperature.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Temperature alarm lower threshold. If the temperature of the battery is lower than the value of this parameter, an
alarm indicating the abnormal temperature is reported.
When the internal temperature of the BTS reaches the Temperature Alarm Lower Threshold, it reports a low
temperature alarm.
When the time mode is set to "ONTIME", you should set this parameter.
If the time mode is set to "DAILY_T", "WEEKLY_T", or "MONTHLY_T", you should set this parameter. This
parameter specifies the first execution time in the day in which the scheduled task is executed.
If the time mode is set to "DAILY_T", "WEEKLY_T", or "MONTHLY_T", you should set this parameter. This
parameter specifies the second execution time in the day in which the scheduled task is executed.
If the time mode is set to "DAILY_T", "WEEKLY_T", or "MONTHLY_T", you should set this parameter. This
parameter specifies the third execution time in the day in which the scheduled task is executed.
If the time mode is set to "DAILY_T", "WEEKLY_T", or "MONTHLY_T", you should set this parameter. This
parameter specifies the fourth execution time in the day in which the scheduled task is executed.
If the time mode is set to "DAILY_T", "WEEKLY_T", or "MONTHLY_T", you should set this parameter. This
parameter specifies the fifth execution time in the day in which the scheduled task is executed.
TRMMAP index
Index of the traffic mapping used by the current adjacent node's gold user.
Loopback time length
Test mode
Duration time for determining that a call is hung up because of poor quality. If the uplink quality or downlink quality in
the measurement reports during the period of Timer for "Bad Quality DISC Statistic" is higher than the value of "Bad
Maximum rate of the accumulated alarm blink duration to the alarm blink measurement period. Assume this threshold
is not 0. When the rate of accumulated alarm blink duration exceeds the threshold, an alarm is reported. For querying
TMSI of the MS
Minimum rate of the accumulated alarm blink duration to the alarm blink measurement period. Assume this threshold
is not 0. When the rate of accumulated alarm blink duration is lower than the threshold, an alarm is reported. For
This timer is a protection timer waiting for a signalling link test acknowledgement message (SLTA) from the peer end
after a signalling link test message (SLTM) is sent to the peer end.
This timer is used to send the signalling link test messages (SLTM) to the peer end regularly.
Name of the data table distributed on the board.
The Ater signaling link operates in the terrestrial transmission or satellite transmission mode. In the areas such as
desert and lake where the terrestrial transmission is difficult, the satellite transmission can be used.
E1 transmission type of the Pb interface. The terrestrial transmission or satellite transmission can be selected. In the
areas such as desert and lake where the terrestrial transmission is difficult, the satellite transmission can be used.
Offset to DST, namely, the adjustment to time.
Cell Reselect Temporary Offset (TO) indicates the temporary correction of C2. This parameter is valid only within the
value specified by "Cell Reselect Penalty Time". For details, see GSM Rec. 05.08 and 04.08. This parameter applies
Number of the cabinet where the board is located
Number of the slot where the board is located
Number of the subrack where the board is located
Type of the host log to be collected.
If this parameter is set to NORMAL, the text log in the \common\fam\famlog directory of the OMU installation path is
Number of the optical port where the main board of the RXU ring is located.
Length of the timer that is started to wait for a channel requested by an incoming BSC handover request message.
When the MSC allows the queuing of incoming BSC handover requests, the BSC6900 starts the queuing procedure
CPU usage threshold for debugging tracing flow control. When the average CPU usage of sliding windows reaches
or exceeds the threshold, debugging tracing flow control is triggered.
Packet queue usage threshold for debugging tracing flow control. When the average packet queue usage of sliding
windows reaches or exceeds the threshold, debugging tracing flow control is triggered.
CPU usage threshold for recovery from debugging tracing flow control. When the average CPU usage of smooth
windows is lower than the threshold, debugging tracing flow control is stopped.
Packet queue usage threshold for recovery from debugging tracing flow control. When the average packet queue
usage of smooth windows is lower than the threshold, debugging tracing flow control is stopped.
Whether to control the debugging tracing flow
Threshold for determining whether the uplink service is preferred. Within the "Flux Measurement Period", if the ratio
of the downlink LLC PDU flux and uplink LLC PDU flux is higher than the threshold, the service type of the MS is
Threshold for determining whether the uplink service is preferred. Within the "Flux Measurement Period", if the ratio
of the uplink LLC PDU flux and downlink LLC PDU flux is higher than the threshold, the service type of the MS is
Traffic mode of the M3UA link set. At present, only the active/standby and load sharing mode is available.
If the M3UA links in the link set work in overriding mode, only one link in the link set works in the active mode, and all
This parameter specifies the data transmission mode between the BTS and the BSC6900. The license control
modes are different in different transmission modes.
Slot number of the transparently transmitting interface board
Transport type of the adjacent node to which the path belongs.
Transport type
Transport type
Transmission type of the BTS
Transmission Type
Whether to configure the optical transmission mode for E1 port 0 of the BTS3006C/BTS3002E. If the optical
transmission mode is configured, the BSC6900 can connect to the BTS through optical fibers.
Whether to configure the optical transmission mode for E1 port 1 of the BTS3006C/BTS3002E. If the optical
transmission mode is configured, the BSC6900 can connect to the BTS through optical fibers.
Whether to configure the optical transmission mode for E1 port 2 of the BTS3006C/BTS3002E . If the optical
transmission mode is configured, the BSC6900 can connect to the BTS through optical fibers.
Whether to configure the optical transmission mode for E1 port 3 of the BTS3006C/BTS3002E. If the optical
transmission mode is configured, the BSC6900 can connect to the BTS through optical fibers.
Whether to enable the limit of the tracing range
Forbidden time of cell reselection
The load handover is triggered when the traffic load in a cell is greater than the value of this parameter.
Port number of the aggregation member
Slot number of the aggregation member
aggregation group number
Specified TRMMAP index of the user panel
TRM load threshold index. The TRM load threshold must be configured.
TRM load threshold index
TRM load threshold index. It is the unique ID of the load threshold.
TRM load threshold index
TRM load threshold index
TRM load threshold index
TRM load threshold index
Transmission resources mapping switch
Trunk group number of the logical port
TRUNK group number
TRUNK group number
Whether to enable the TRX aiding function. Four aiding modes are available. BCCH aiding: The main BCCH is aided
to another normal TRX in this cell. BCCH aiding switchback: BCCH aiding switchback functions after the originally
Duration
Frequency hopping index of the channel in the TRX
Index of a TRX, uniquely identifying a TRX in a BSC6900.
The ID of TRX added in the main location group, the TRX ID must be globally unique. The same TRX cannot be
bound by the TRX boards in a same location group for multiple times.
Index of TRX 1
Index of TRX 10
Index of TRX 11
Index of TRX 12
Index of TRX 13
Index of TRX 14
Index of TRX 15
Index of TRX 16
Index of TRX 17
Index of TRX 18
Index of TRX 19
Index of TRX 2
Index of TRX 20
Index of TRX 21
Index of TRX 22
Index of TRX 23
Index of TRX 24
Index of TRX 3
Index of TRX 4
Index of TRX 5
Index of TRX 6
Index of TRX 7
Index of TRX 8
Index of TRX 9
List of IDs of carriers for frequency hopping.
List of TRX indexes. You can specify one TRX index or more TRX indexes, for example, 1 or 0&1&2&&5 in the same
BTS.
Mobile allocation index offset (MAIO) of the channel in the TRX
Number of a TRX in a BTS. The number of a TRX is unique in a BTS.
Allowed number of carriers bound to a board.
Number of the channel bound to the TRX on the TRX board. TRX Pass No. of the DTRU/DRRU/BTS3900B of the
BTS in separate mode must be 0 or 1; TRX Pass No. of the QTRU/MRFU/GRFU/BTS3900E of the BTS in separate
TRX board pass number in the sub-location group to which the TRX of the main location group is bound
This parameter specifies whether the TRX priority is considered during channel assignment. When the parameter is
set to YES, the smaller the parameter "TRX Priority" in the command "SET GTRXDEV" is, the higher priority the TRX
Type of the TRX board bound to the TRX
It indicates the Ater interface timeslot number
It indicates the A interface timeslot number. The parameter supports multiple values.
Timeslot number
Timesolt of bearing channels
Number of the timeslot on the port
Bearer E1/T1 port timeslot of PPP link.
Bearer E1/T1 port timeslot of MP link.
Timeslot of the E1/T1 link carrying the PPP link. The timeslot of an E1 port cannot be used by different PPP links.
The TSC is short for the Training Sequence Code.
The TSC must be the same as the BCC. The delay equalization is performed by using the specified TSC when the
Number of idle timeslots. You can configure up to 128 idle timeslots for the BTS at a time. A BTS can be configured
with up to 512 idle timeslots.
Whether to allow TSC planning. If this parameter is set to No, the TSC values in all MA groups of the cell cannot be
modified. In this case, the TSC values are automatically refreshed to the BCC values of the cell.
Timeslot cross index
Duration in timeslot mode
Index of the monitoring timeslot. The index is unique in a BTS.
Name of the scheduled task.
Time slots for Ater operation and maintenance. These time slots are provided by the ports connected to the Ater
connection path.
The 64 kbit/s timeslots on the port are numbered from 1 to 31.
Number of the slot where the main board of the RXU ring is located. The slot No. is unique in the same BTS.
Timeslot number of Pb signaling link
Assignment priority level of the channel. If this parameter is less, the assignment priority level of the channel is
higher.
Maximum degree by which the output power of the multi-density TRX board can exceed the maximum output power
within a short time
Fast flux measurement duration. Normal flux measurement is performed after the fast flux measurement lasts over
the period specified by this parameter.
Whether to enable fast flux detection. When this parameter is set to Open, fast timeslot adjustment is possible after
the TBF is set up.
Rate of the monitoring timeslot
Number of the subrack where the main board of the RXU ring is located. The subrack No. is unique in the same
BTS.
Test mode
Test timeslot
Type of battery test
Test Type. PIM:passive intermodulation test.
This parameter specifies whether to allow the BTS to enable the TRX Intelligent Shutdown on Timeslot Level feature.
When this parameter is set to YES and the BTS supports this feature, the BTS will periodically report the number of
RXU topology type, that is, RXU ring topology or RXU chain topology. In the case of the ring topology, the optical
ports of the head and tail boards must be specified. In the case of the chain topology, only the optical port of the
TTL(Time to Live) of the PING packet
Indicates the live time of the packet for CFM link tracing detection
If the number of channels (including PDCH and TCH) occupied on a cell that can be disabled is lower than this
threshold, the procedure for disabling the cell can be triggered.
This parameter specifies the end time of a period during which the cell is disabled.
This parameter specifies the start time of a period during which the cell is disabled.
This parameter specifies whether to enable the Dynamic Cell Power Off feature. When this parameter is set to
ENABLE, the BSC can disable the cell within the period of time specified by "TURNOFFCELLSTRTIME" and
When the load of the same coverage cell is higher than this threshold for a period, the disabled cell is enabled.
Temperature alarm upper threshold. If the temperature of the battery is higher than the value of this parameter, an
alarm indicating the abnormal temperature is reported.
Temperature upper threshold of the cabinet. When the cabinet temperature is higher than this parameter, an alarm
indicating the abnormal cabinet temperature is reported.
Value of the timer for reserving the channels in the observed cell
Value of the timer for reserving the TRXs in the observed cell
Value of the timer for reserving the TCHFs in the serving cell
Value of the timer for waiting for the response to information collection
Value of the timer for searching for the MS
Value of the timer for activating the reserved resources of the BTS
Value of the timer for waiting for the synchronization report from the BTS
Tx-integer (T for short). This parameter specifies the number of timeslots between two transmissions when an MS
sends multiple consecutive channel requests.
The maximum power that operators 1 can use on pass A of MRRU board.
The maximum power that operators 2 can use on pass A of MRRU board.
The maximum power that operators 3 can use on pass A of MRRU board.
The maximum power that operators 4 can use on pass A of MRRU board.
The maximum power that operators 1 can use on pass B of MRRU board.
The maximum power that operators 2 can use on pass B of MRRU board.
The maximum power that operators 3 can use on pass B of MRRU board.
The maximum power that operators 4 can use on pass B of MRRU board.
Transmit bandwidth of IP path
Transmit bandwidth
Indicates the interval between the two sent PING packets
Extension transmission timeslots of random access. This parameter determines the interval of sending another
channel request after the MS fails to request a channel.
Type of the subrack
Explanation of the finish type of the batch commands
1. ANY_ERR_RETURN: If there is a command whose execution fails, the execution of the batch commands is
This parameter specifies the frequency band of new cells. Each new cell can be allocated frequencies of only one
frequency band. Once the frequency band is selected, it cannot be changed.
Type of the PCU
Frequency band to which the newly added cell belongs. Only one frequency band can be selected as the frequency
band of each new cell and it cannot be changed after the selection. To modify the frequency band of the new cell,
Type of a cabinet
Cell type. Currently, the fast BTS construction is available for only GSM900 and DCS1800 cells.
Power attenuation factor of uplink tributary 0
Whether there is a TMA on uplink tributary 0
Index of uplink tributary 0. Each uplink tributary can be configured with a maximum of 12 TRXs. This parameter
indicates the serial number of a TRX on the uplink tributary.
TRX board pass number connected to uplink tributary 0
Number of the slot where the TRX board that connects to uplink tributary 0 is located
Number of the subrack where the TRX board that connects to uplink tributary 0 is located
Power attenuation factor of uplink tributary 1
Whether there is a TMA on uplink tributary 1
Index of uplink tributary 1. Each uplink tributary can connect to a maximum of 12 TRXs. This parameter indicates the
serial number of a TRX on the uplink tributary.
TRX board pass number connected to uplink tributary 1
Number of the slot where the TRX board that connects to uplink tributary 1 is located
Number of the subrack where the TRX board that connects to uplink tributary 1 is located
Service priority of call reestablishment when CS services are preferred. This parameter is used for the flow control in
the case of Abis over IP/HDLC.
Service priority of the CS emergency call when CS services are preferred. This parameter is used for the flow control
in the case of Abis over IP/HDLC.
Service priority of the CS MS-originated call when CS services are preferred. This parameter is used for the flow
control in the case of Abis over IP/HDLC.
Service priority of the CS MS-terminated call when CS services are preferred. This parameter is used for the flow
control in the case of Abis over IP/HDLC.
Service priority of the incoming BSC handover when CS services are preferred. This parameter is used for the flow
control in the case of Abis over IP/HDLC.
Service priority of the intra-BSC handover when CS services are preferred. This parameter is used for the flow
control in the case of Abis over IP/HDLC.
Priority of other services when CS services are preferred. This parameter is used for the flow control in the case of
Abis over IP/HDLC.
PS service priority when CS services are preferred. This parameter is used for the flow control in the case of Abis
over IP/HDLC.
Priority of supplementary services when CS services are preferred. This parameter is used for the flow control in the
case of Abis over IP/HDLC.
VBS service priority when CS services are preferred. This parameter is used for the flow control in the case of Abis
over IP/HDLC.
VGCS service priority when CS services are preferred. This parameter is used for the flow control in the case of Abis
over IP/HDLC.
In A over IP, if the parameter is set to ON, the circuit IE in the A interface extended signaling must be processed in
the same way as that in A over non-IP. Otherwise, the A interface extended signaling cannot carry circuit-type IE.
Whether the BSC selects the TCHs on the link that reports an RAI alarm.
Reestablish service priority of a PS preferred call
CS emergency call service priority of a PS preferred call
CS original call service priority of a PS preferred call
CS terminated call service priority of a PS preferred call
BSC handover service priority of a PS preferred call
BSC intra handover service priority of a PS preferred call
Other service priority of a PS preferred call
PS service priority of a PS preferred call
Supplement service priority of a PS preferred call
VBS service priority of a PS preferred call
VGCS service priority of a PS preferred call
In case of intra-BSC, if this parameter is set to ON, the same channel type and voice version as those of the original
channel are selected.
UDP multiplexing mode of the receiving party. The mode that does not support the function of compressing the RTP
header indicates that the receiving party supports the UDP MUX RTP header but not the function of compressing the
UDP multiplexing mode of the sending party. If the mode that does not support the function of compressing the RTP
header indicates that the sending party supports the UDP MUX RTP header but not the function of compressing the
UDP port number of the local NSVL. The setting of this parameter must be consistent with the setting at the SGSN
side.
UDP port number of the remote NSVL. The setting of this parameter must be consistent with the setting at the SGSN
side.
Group to which the operator belongs. This parameter is used to limit the right of the operator.
Upper humidity threshold for the environment alarm box to report an alarm indicating that the ambient humidity is too
high. If the ambient humidity of the BTS is higher than this threshold, the environment alarm box reports the alarm.
Used to identify the uplink access message from the MS. The value 64 is invalid.
Unit time for the error code ratio test
Upper limit for triggering an alarm
Upper limit of the alarm. This parameter is valid for the analog port.
Minimum interval between two consecutive uplink power control commands
Current call is an AMR full-rate call, and when the uplink receive quality is greater than the threshold, Huawei III
power control is performed.
Current call is an AMR full-rate call, and when the uplink receive quality is lower than the threshold, Huawei III power
control is performed.
Current call is an AMR half-rate call, and when the uplink receive quality is greater than the threshold, Huawei III
power control is performed.
Current call is an AMR half-rate call, and when the uplink receive quality is lower than the threshold, Huawei III power
control is performed.
The P/N criterion must be met for triggering a UL BQ handover. That is, the UL BQ handover can be triggered only if
P measurement reports among N measurement reports meet the triggering conditions. This parameter corresponds
The P/N criterion must be met for triggering a UL BQ handover. That is, the UL BQ handover can be triggered only if
P measurement reports among N measurement reports meet the triggering conditions. This parameter corresponds
If the ratio of uplink flux to downlink flux is greater than or equal to the threshold during the fast flux measurement,
the uplink services takes priority.
Duration for uplink data transmission on the original channel if the TC resources are changed before and after the
handover
Number of downlink GRPS TBF RLC blocks sent before RRBP field is sent
If the UL receive level remains lower than the "Edge HO UL RX_LEV Threshold" for a period, the edge handover is
triggered.
Number of downlink GRPS TBF RLC blocks sent before RRBP field is sent
Period of acknowledging the EGPRS TBF RLC uplink data block
Filter adjustment factor for uplink power control. If this parameter is set to a large value, the filtered values become
smooth, thus reducing the impact of poor measurement reports on the filtered values. If this parameter is set to a
Current call is a full-rate call, and when the uplink receive quality is greater than the threshold, Huawei III power
control is performed.
Current call is a full-rate call, and when the uplink receive quality is lower than the threshold, Huawei III power control
is performed.
Current call is a half-rate call, and when the uplink receive quality is greater than the threshold, Huawei III power
control is performed.
Current call is a half-rate call, and when the uplink receive quality is lower than the threshold, Huawei III power
control is performed.
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
When the uplink load of a cell is larger than the value of this parameter and is smaller than "2G Cell UL Overload
Congest Thred", the uplink of the cell is in the basic congestion status.
When the network receives measurement reports, in consideration of the accuracy of a single measurement report,
the measurement values in certain measurement reports are filtered to represent the radio operating environment.
Maximum permissible adjustment step when the BSC decreases the uplink transmit power
Maximum permissible adjustment step when the BSC increases the uplink transmit power
When the uplink load of a cell is greater than the value, the uplink of the cell is in the overload congestion status.
After the BSC delivers the power control command, it should wait for a certain period before affirming the effect of
the power control. Therefore, the MR that power control decision is based on cannot accurately reflect the radio
The MS transmit power is decreased only when the quality level of the MS transmit signal is smaller than the value of
the parameter. If (the uplink receive level - MAX Up Adj. PC Value by Qual) is smaller than "UL RX_LEV Lower
The MS transmit power is increased only when the quality level of the MS transmit signal is greater than the value of
the parameter. If (the uplink receive level + MAX Up Adj. PC Value by Qual) is greater than "UL RX_LEV Upper
When the network receives measurement reports, the measurement values in several straight measurement reports
are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number
In the case of power control, when the uplink receive quality is not smaller than "UL Qual. Bad Trig Threshold", the
actual "UL RX_LEV Upper Threshold" is increased by "UL Qual. Bad UpLEVDiff".
In the case of power control, when the uplink receive quality is not smaller than "UL Qual. Bad Trig Threshold", the
actual "UL RX_LEV Upper Threshold" is increased by "UL Qual. Bad UpLEVDiff".
An emergency handover due to bad quality is triggered when the uplink receive quality is not smaller than "UL Qual.
Threshold".
The value of this parameter corresponds to multiplying quality level 0 to 7 by 10. An emergency handover can be
triggered only when the uplink receive quality of the MS is greater than the value of this parameter.
The value of this parameter corresponds to multiplying quality level 0 to 7 by 10. An emergency handover can be
triggered only when the uplink receive quality of the MS is greater than the value of this parameter.
This parameter specifies the uplink signal strength factor multiplied by 10 during the calculation of the uplink power
control step. The uplink signal strength factor is a coefficient indicating how much the signal strength is considered
When the network receives measurement reports, the measurement values in several straight measurement reports
are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number
When the uplink receive level reaches the threshold, Huawei III power control is performed.
When the uplink receive level is lower than the threshold, Huawei III power control is performed.
When the network receives measurement reports, the measurement values in several straight measurement reports
are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number
This parameter specifies the uplink quality level factor multiplied by 10 during the calculation of the uplink power
control step. The uplink quality level factor is a coefficient indicating how much the quality level is considered during
When the network receives measurement reports, the measurement values in several straight measurement reports
are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number
When the network receives measurement reports, the measurement values in several straight measurement reports
are filtered to reflect the radio operating environment for the sake of accuracy. This parameter specifies the number
Signal strength factor for the protective limitation on calculating the uplink power control adjustment step. The
calculated step value cannot exceed the step value that is obtained on the basis of the signal strength protection
Signal strength factor for the protective limitation on calculating the uplink power control adjustment step. The
calculated step value cannot exceed the step value that is obtained on the basis of the signal strength protection
When the uplink receive level reaches the threshold, Huawei II power control is performed.
When the uplink receive level is below the threshold, Huawei II power control is performed.
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Based on the RQI in the call measurement report, the BTS and MS automatically adjust the current speech coding
rate according to the related algorithm. The coding rate adjustment threshold is the threshold of RQI. The RQI
Whether a UL subcell to OL subcell handover is allowed
Number of uplink GRPS TBF RLC blocks sent before an acknowledgement is required
Whether the crosstalk optimization function over the Um interface is allowed. If this parameter is set to YES when
call drops occur on the Um interface, this function can avoid crosstalk due to very early assignment of the channel
Timer of penalty on a neighboring cell when a handover fails due to faults of air interface connection.
Phase tag for GSM protocols that the Um interface supports
Whether to support the balanced mode or the unbalanced mode. When this parameter is set to YES, you can set the
DIP switches on the interface boards. You do not need to set the DIP switches by turning them inwards or outwards.
Retry times after the peer response timer expires during NSVC unblocking
Abnormally alarm triggering threshold when the ANT_A tributary antenna current is too light. When the actual current
is lower than the configured value, the ALD Current Abnormally Alarm is triggered with the corresponding alarm
Abnormally alarm triggering threshold when the ANT_B tributary antenna current is too light. When the actual current
is lower than the configured value, the ALD Current Abnormally Alarm is triggered with the corresponding alarm
Abnormally alarm triggering threshold when the RET tributary antenna current is too light. When the actual current is
lower than the configured value, the ALD Current Abnormally Alarm is triggered with the corresponding alarm
Abnormally alarm clearance triggering threshold when the ANT_A tributary antenna current is too light. When the
actual current is higher than the configured value, the ALD Current Abnormally Alarm disappears with the
Abnormally alarm clearance triggering threshold when the ANT_B tributary antenna current is too light. When the
actual current is higher than the configured value, the ALD Current Abnormally Alarm disappears with the
Abnormally alarm clearance triggering threshold when the RET tributary antenna current is too light. When the actual
current is higher than the configured value, the ALD Current Abnormally Alarm disappears with the corresponding
Index of upper-level BTS connected to the BTS
Number of the upper-level BTS. The number is unique in a BSC6900.
Index type of upper-level BTS connected to the BTS
Index type of the upper-level BTS
Name of the upper-level BTS connected to the BTS. The BTS name is unique within a same BSC6900. This
parameter cannot contain , ; = " ' more than two (include two) %, more than two (include two) space, more than three
Name of the upper-level BTS. The name is unique in a BSC6900. The invalid characters (\, /, :, *, ?, ", <, >, |, and #)
cannot appear in the name.
Update code for a simple cell broadcast message.
This parameter together with "Code" uniquely identifies a cell broadcast message.
Default coding scheme of the uplink GPRS link. If the uplink adopts the dynamic adjustment coding scheme, this
parameter can be used to set the coding scheme for transmission during initial access. If the uplink uses the fixed
Default coding scheme of the uplink EDGE link. If the uplink adopts the dynamic adjustment coding scheme, this
parameter can be used to set the coding scheme for transmission during initial access. If the uplink uses the fixed
Uplink multiplex threshold of dynamic channel conversion. When the subscriber number on the channel reaches the
value (threshold/10), the dynamic channel conversion application is triggered. We recommand that the value of
Default coding scheme used on the uplink EGPRS2-A link. If the uplink uses the dynamic coding scheme, this
parameter specifies the coding scheme that is used for the transmission in initial access. If the uplink uses the fixed
Fixed coding scheme that is used on the uplink EGPRS2-A link. If the uplink uses the fixed coding scheme, this
parameter can be set to any one in MCS1-6 and UAS7-11. If the uplink uses the dynamic coding scheme, this
Inactive period of extended uplink TBF. After the network side receives the last uplink RLC data block
(CountValue=0) of the MS supporting the extended uplink TBF, the uplink TBF is not released immediately. Instead,
Adjustment mode of the uplink GPRS link coding scheme. If the fixed coding scheme is used, this parameter is a
value ranging from CS1 to CS4. If the dynamic coding scheme is used, this parameter is set to UNFIXED.
Coding scheme of the uplink EDGE link. If the uplink uses the fixed coding scheme, this parameter is set to a value
ranging from MCS1 to MCS9. If the uplink uses the dynamic adjustment coding scheme, this parameter is set to
One of the thresholds to determine whether the uplink interference exists. If the uplink level is not smaller than
"Interf.of UL Level Threshold" and the uplink quality of the channel is not less than "Interf.of UL Qual. Threshold", the
One of the thresholds to determine whether the uplink interference exists. If the uplink level is not smaller than
"Interf.of UL Level Threshold" and the uplink quality of the channel is not less than "Interf.of UL Qual. Threshold", the
Maximum time in which a user uses the uplink of its VGCS call continuously when the BTS works in fallback mode
Size of the OML/ESL/EML Uplink LAPD Window
Whether to allow MS power control
Upper class transport resource group No. It is valid only when " Is First Class Transport Resource Group " is set to
NO.
Upper number of the logical port
If the difference between uplink receive levels of calls within the same timeslot is greater than "Offset of the
difference between uplink received levels" for P seconds among N seconds, the call with weak uplink receive level
After the existing uplink receive level, uplink receive level after the previous optimization, and the value of this
parameter are weight-averaged, the uplink receive level after the optimization at this time is obtained and used for
If the difference between uplink receive levels of calls within the same timeslot is greater than "Offset of the
difference between uplink received levels" for P seconds among N seconds, the call with weak uplink receive level
This parameter specifies whether the transmission of point-to-point short messages is disabled. If necessary, the
transmission of the uplink short messages in a specific cell can be disabled so that sufficient radio channels can be
Delay of releasing the non-extended uplink TBF. After receiving the last uplink RLC data block (CountValue=0), the
network side sends the message Packet Uplink Ack/Nack with FAI=1 to notify the MS of releasing the uplink TBF.
Retransmission threshold when the coding mode of the uplink TBF is changed from CS2 to CS1. When the
retransmission rate of the uplink TBF is greater than or equal to this threshold, the coding mode of the uplink TBF is
Retransmission threshold when the coding mode of the uplink TBF is changed from CS3 to CS2. When the
retransmission rate of the uplink TBF is greater than or equal to this threshold, the coding mode of the uplink TBF is
Retransmission threshold when the coding mode of the uplink TBF is changed from CS4 to CS3. When the
retransmission rate of the uplink TBF is greater than or equal to this threshold, the coding mode of the uplink TBF is
Retransmission threshold when the coding mode of the uplink TBF is changed from CS1 to CS2. When the
retransmission rate of the uplink TBF is less than or equal to this threshold, the coding mode of the uplink TBF is
Retransmission threshold when the coding mode of the uplink TBF is changed from CS2 to CS3. When the
retransmission rate of the uplink TBF is less than or equal to this threshold, the coding mode of the uplink TBF is
Retransmission threshold when the coding mode of the uplink TBF is changed from CS3 to CS4. When the
retransmission rate of the uplink TBF is less than or equal to this threshold, the coding mode of the uplink TBF is
Whether to allow cell urgent reselection. If this parameter is set to PERMIT and [NC2 Load Reselection Switch is set
to Support, the load of the target cell is involved in the algorithm for NC2 cell reselection.
Mode of querying the information on an MS
Whether to support USF granularity 4
User name of the FTP server
User name for the FTP server. When the FTPServer.exe file downloaded through the LMT is installed, the user
name is admin.
Start time when the TRX energy saving function is enabled for the BTS3002E.
End time when the TRX energy saving function is enabled for the BTS3002E.
Upper temperature threshold for the environment alarm box to report an alarm indicating that the ambient
temperature is too high. If the ambient temperature of the BTS is higher than this threshold, the environment alarm
When a UL subcell-OL subcel handover decision is performed to a call, the BSC determines whether the number of
handover failures reaches the "MaxRetry Time after UtoO Fail". If the number reaches the threshold, the UL subcell
After an MS performs a OL subcell to UL subcell handover successfully, the MS cannot be handed over to the OL
subcell again within the value of the parameter.
One of the parameters that determine the coverage of the OL subcell and of the UL subcell. "UtoO HO Received
Level Threshold", "OtoU HO Received Level Threshold", "ReceiveQualThrshAMRFR", "TA Threshold", and "TA
When this parameter is set to YES, the existing call is performed in the OL subcell, and "OL to UL HO Allowed" is set
to YES, an OL subcell to UL subcell handover is triggered if the traffic volume in the UL subcell is smaller than "En
Hierarchical handover period of the load handover from the UL subcell to the OL subcell. If the channel seizure ratio
of the UL subcell is greater than the UL subcell general overload threshold, all the calls in the cell send handover
Hierarchical level step of the load handover from the UL subcell to the OL subcell
This parameter specifies the type of a 3G cell. A cell type can be Frequency Division Duplex (FDD) or Time Division
Duplex (TDD).
Vendor code of the RET antenna
This parameter is used to limit the maximum number of channels that can be used by the VGCS in a cell. This
prevents too many channels in the cell from being occupied by the VGCS and thus prevents public network services
This parameter specifies whether the preemption of channels between public network services and the VGCS is
allowed when preemption conditions are met.
This parameter is used to reserve a certain number of channels in a cell for the Voice Group Call Service (VGCS) to
use directly. The specified channels are unavailable to public network services.
This parameter specifies the usage threshold of the CPU for VIP user calls that can be admitted. When the usage of
a CPU is greater than this threshold, the new service requests from VIP users are transferred to another CPU for
Is VIP Cell.The parameter is used for BSC6900 flow control.
This parameter specifies the eMLPP priority value corresponding to the VIP call. When the eMLPP(Enhanced Multi-
Level Precedence and Pre-emption service) priority value of a user is greater than or equal to the value of this
This parameter specifies the usage threshold of the CPU for VIP user calls that are transferred from other CPUs.
When the usage of a CPU is greater than this threshold, the VIP service requests transferred from other CPUs are
If the parameter is set to Disable, the added IP path is not configured with the VLAN ID. If the parameter is set to
Enable, the added IP path is configured with the VLAN ID.
Specified Vlan enabling flag
VLANID flag of first local IP address
VLANID Flag of second Local IP address
VLANID of the IP address of the specified next hop
VLAN of the MA in the MD
VLAN ID of the service type
VLAN to which the maintenance association belongs in the maintenance domain.
VLAN ID of first Local IP address
VLAN ID of second Local IP address
VLAN priority
VLAN priority level of the service type. This parameter helps to determine the packet service priority level at the data
link layer on the Ethernet. If this parameter is set to 0, the service type has the highest VLAN priority level. If this
VLAN switch for the service type
Speech version supported by a cell
24V voltage alarm switch
Upper limit for triggering a 24 V voltage sensor alarm
Lower limit for triggering a 24 V voltage sensor alarm
48V voltage alarm switch
Upper limit for triggering a 48V voltage sensor alarm
Lower limit for triggering a 48V voltage sensor alarm
Whether to enable the standing wave alarm parameters to be configured
This parameter specifies a condition for generating a BTS alarm. This parameter together with "VSWR TRX error
threshold" is used to detect whether the antenna system connected to the TRX is faulty.
Filtering times of serious standing wave alarms
Standing wave alarm threshold. When the VSWR is greater than the value of this parameter, the TRX reports a
standing wave alarm.
Serious standing wave alarm threshold. When the VSWR is greater than the value of this parameter, the TRX
reports a serious standing wave alarm.
This parameter specifies a condition for generating a BTS alarm. This parameter together with "VSWR TRX
unadjusted threshold" are used to check whether the antenna system connecting to the TRX is faulty. If the value of
V-version number of the BTS software
This timer is used to set the time of waiting for a ReleaseIndication message after a ChannelRelease message is
sent. If the timer expires, the channel is deactivated.
When the BSC6900 sends a ChannelRelease message and the current call uses the AMRFR encoding mode, the
timer T3109 (AMRFR) is started. If the BSC6900 receives the ReleaseIndication message before the T3109
When the BSC sends a ChannelRelease message and the current call uses the AMRHR encoding mode, the timer
T3109 (AMRHR) is started. If the BSC receives the ReleaseIndication message before the T3109 (AMRHR) timer
Timer of waiting for the MS's response to the location measurement request sent from the BSC. If the BSC does not
receive the measurement information reported by the MS before the timer expires, then the MS location fails.
The TCHs reserved for the emergency call are assigned to the user during the service assignment. If the TCHs are
not assigned to the emergency call within a period, the TCHs are released from the reservation queue.
When the dynamic PDCH needs to use MAIO of the SDCCH, the SDCCH is not allowed to be assigned to new calls
within the value of the parameter. After the timer expires, check whether the SDCCH is idle. If the SDCCH is idle,
Timer of waiting for the SMLC's response to the MS location request sent from the MSC. If the SMLC does not send
any response to the MS location request before the timer expires, then the MS location fails. In this case, the BSC
Whether to start the heating equipment of the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Water sensor alarm switch
Whether to limit the operation weekday of the operator. If the weekday needs to be limited, see the description of
"Week".
This parameter is used to select the location of a cell, east or west longitude.
Whether to start the humidification equipment of the BTS.
In multi-mode scenario, the value of this parameter in one mode must be the same as the value of the corresponding
Whether to trigger an active/standby port switchover. If this parameter is set to YES, an active/standby port
switchover is triggered when a fault is detected on the active port. If this parameter is set to NO, an active/standby
Whether to start the dynamic adjustment of the LAPD window. If this parameter is set to ALLOW, the LAPD transmit
and receive window is enlarged when the delay is increased, which improves the transmission efficiency of LAPD but
You can select multiple weekdays.
Working mode of the M3UA link set, including M3UA_ASP and M3UA_IPSP. For details about the ASP and IPSP,
see the RFC4666.
Time when the BTS stops checking for a radio link alarm. If this time is up, the BTS stops checking for or reporting a
radio link alarm until the next alarm detection start time is up.
Whether to enable the BTS to report a major radio link alarm. If this parameter is set to YES, the BTS reports a major
radio link alarm when a radio link warning is not cleared within "WLARP". If this parameter is set to NO, the BTS
Period for clearing a radio link warning. If a radio link warning is cleared within this period, the BTS reports the
recovery alarm for the warning. If a radio link warning is not cleared within this period, the BTS determines whether to
Time when the BTS starts to check for a radio link alarm. If this time is up, the BTS starts to check for and report a
radio link alarm.
Whether to enable the BSC to deliver radio link alarm parameters to the BTS. If this parameter is set to YES, the
BSC delivers the radio link alarm parameters to the BTS. If this parameter is set to NO, the BSC does not deliver the
Flag of the work area to be formatted
Working mode of the RXU board
Work mode of subrack
Working mode. E1: The E1 system is recommended by the IUT-T. E1 carries signals at 2.048 Mbit/s. G.703 defines
the electrical specification and G.704 defines the frame format for E1 telecommunication lines. The E1 system is
BTS port working mode. This parameter must be consistent with that of the peer. Work mode of a BTS. A BTS can
work in the following modes:
Window size of the Ater signaling link
Time for which the BTS waits to swap the OML after the OML is interrupted. With this parameter, the BTS does not
swap the OML when the OML is interrupted transiently.
Waiting time before establishing a link in the reverse direction after the transmission of a BTS is disrupted
Wait to restore time
Time zone
Feature ID
GBFD-110502
GBFD-110502
GBFD-110502
GBFD-116601
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-114201
GBFD-114201
GBFD-117702
GBFD-117301
GBFD-113101
MRFD-210301
GBFD-118201
GBFD-116801
GBFD-119110
GBFD-119110
GBFD-511002
GBFD-511002
GBFD-113201
GBFD-511002
GBFD-119501
GBFD-511002
GBFD-511002
GBFD-511002
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-119305
GBFD-110402
GBFD-111101
GBFD-115501
GBFD-115701
GBFD-115502
GBFD-115701
GBFD-115507
GBFD-115701
GBFD-110501
GBFD-510502
GBFD-118201
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-110601
GBFD-510501
GBFD-111202
GBFD-111705
GBFD-111705
GBFD-111202
GBFD-111804
GBFD-118201
GBFD-119204
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-118201
GBFD-118201
GBFD-118201
GBFD-118201
MRFD-210304
GBFD-111202
GBFD-111202
GBFD-115602
GBFD-115602
GBFD-115602
GBFD-115602
GBFD-115602
GBFD-115602
GBFD-115602
GBFD-115602
GBFD-115505
GBFD-115505
MRFD-210502
MRFD-210502
GBFD-115505
GBFD-115505
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-111202
MRFD-210304
GBFD-113801
MRFD-210304
MRFD-210304
GBFD-116401
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-118602
GBFD-115601
GBFD-115601
GBFD-115601
GBFD-115601
GBFD-115601
GBFD-115601
GBFD-115601
GBFD-510002
GBFD-510002
GBFD-118605
GBFD-114101
GBFD-113101
GBFD-111005
GBFD-119401
GBFD-116201
GBFD-111005
GBFD-111803
GBFD-111203
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-119115
GBFD-115402
MRFD-210502
GBFD-115402
MRFD-210502
MRFD-210304
MRFD-210304
GBFD-111202
MRFD-210601
GBFD-111202
MRFD-210601
GBFD-111202
MRFD-210601
GBFD-111202
MRFD-210601
GBFD-111202
MRFD-210601
GBFD-111202
MRFD-210601
GBFD-115503
GBFD-117601
GBFD-115506
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-110703
GBFD-115502
GBFD-115502
GBFD-115506
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-115503
GBFD-111803
GBFD-111803
GBFD-115703
GBFD-115703
GBFD-115703
MRFD-210602
GBFD-118601
GBFD-118602
None
MRFD-210304
GBFD-115603
GBFD-115603
GBFD-115603
GBFD-115603
GBFD-115402
GBFD-118201
GBFD-510401
MRFD-210501
GBFD-510401
MRFD-210501
GBFD-118611
GBFD-118622
GBFD-111202
MRFD-210602
GBFD-111202
GBFD-510104
GBFD-111202
GBFD-111804
GBFD-118602
GBFD-114701
GBFD-119904
GBFD-119904
GBFD-119904
GBFD-119904
GBFD-119904
GBFD-119904
GBFD-119904
GBFD-119904
MRFD-210301
MRFD-210401
MRFD-210401
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-118609
GBFD-118611
GBFD-118622
GBFD-111804
GBFD-111804
GBFD-111804
MRFD-210304
MRFD-210304
GBFD-110502
GBFD-110607
GBFD-113201
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-510901
GBFD-110502
GBFD-111203
GBFD-111803
GBFD-111705
GBFD-111705
GBFD-111203
GBFD-111803
GBFD-111203
GBFD-111803
GBFD-113201
GBFD-114402
GBFD-114402
GBFD-116901
GBFD-116901
GBFD-116901
GBFD-111203
GBFD-117701
GBFD-111203
GBFD-114701
MRFD-210301
MRFD-210301
GBFD-111203
GBFD-116902
GBFD-111202
GBFD-111804
GBFD-110302
GBFD-111202
MRFD-210601
GBFD-111202
MRFD-210601
None
None
MRFD-210305
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118609
MRFD-210301
GBFD-115501
GBFD-115502
GBFD-111202
GBFD-118601
GBFD-111202
MRFD-210305
MRFD-210305
None
GBFD-111804
MRFD-210304
MRFD-210304
None
None
None
None
MRFD-210502
MRFD-210502
GBFD-111203
MRFD-210305
MRFD-210301
GBFD-111004
GBFD-114101
None
GBFD-118609
GBFD-118609
GBFD-111605
GBFD-111605
GBFD-114401
GBFD-114401
GBFD-114401
GBFD-110601
GBFD-510501
GBFD-111202
GBFD-118201
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-113725
GBFD-110801
GBFD-110802
GBFD-111202
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
GBFD-110101
GBFD-113701
GBFD-510002
GBFD-510002
GBFD-118603
GBFD-510002
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-119902
GBFD-119902
GBFD-119902
GBFD-111804
GBFD-111806
GBFD-113725
GBFD-114201
GBFD-114302
GBFD-114301
GBFD-114302
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-118609
GBFD-118609
GBFD-110801
GBFD-110802
GBFD-113801
GBFD-118201
GBFD-119902
GBFD-119902
GBFD-119902
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-510002
GBFD-510002
None
None
None
GBFD-111705
GBFD-118611
GBFD-118622
MRFD-210304
GBFD-111202
GBFD-111202
GBFD-110601
GBFD-510501
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-510501
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
MRFD-210301
MRFD-210301
None
None
None
None
GBFD-111202
GBFD-111202
GBFD-117802
GBFD-113602
GBFD-113602
GBFD-111203
MRFD-210305
GBFD-111003
GBFD-110301
GBFD-118602
GBFD-111602
GBFD-111803
GBFD-113726
GBFD-113601
GBFD-118201
GBFD-118201
GBFD-116902
GBFD-118605
MRFD-210301
GBFD-118201
GBFD-113601
GBFD-118601
GBFD-117701
GBFD-118621
GBFD-115001
GBFD-115001
GBFD-114701
GBFD-113601
GBFD-115001
GBFD-115001
GBFD-115001
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
GBFD-114701
GBFD-114701
GBFD-114701
GBFD-118201
GBFD-113726
GBFD-113726
GBFD-114701
GBFD-114101
GBFD-110802
MRFD-210301
GBFD-110303
GBFD-111003
MRFD-210301
MRFD-210301
GBFD-117701
GBFD-117702
GBFD-117701
GBFD-117702
GBFD-119305
GBFD-119305
MRFD-210502
MRFD-210401
MRFD-210401
None
None
None
None
None
None
None
MRFD-210602
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111801
GBFD-113726
GBFD-111801
GBFD-111202
GBFD-111611
GBFD-111202
GBFD-118601
GBFD-118601
GBFD-111202
GBFD-118601
GBFD-118605
GBFD-111202
GBFD-111202
GBFD-118401
GBFD-111202
GBFD-118201
MRFD-210602
MRFD-210305
GBFD-118601
GBFD-117702
GBFD-118601
GBFD-110802
GBFD-111202
GBFD-118401
GBFD-111202
GBFD-118601
GBFD-111605
GBFD-110703
GBFD-118103
GBFD-111202
GBFD-118401
GBFD-111202
GBFD-510701
GBFD-111202
GBFD-118609
GBFD-111207
GBFD-111202
GBFD-117802
GBFD-118602
GBFD-119001
GBFD-119001
GBFD-119001
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-110801
GBFD-110802
MRFD-210301
GBFD-114101
GBFD-114101
GBFD-111202
GBFD-111202
MRFD-210301
GBFD-110503
GBFD-111202
GBFD-113701
GBFD-111101
GBFD-510702
GBFD-111202
GBFD-118605
GBFD-118605
None
GBFD-110401
GBFD-110402
GBFD-113601
GBFD-113601
GBFD-113601
GBFD-113601
GBFD-113601
GBFD-110401
GBFD-110301
GBFD-118605
GBFD-113601
GBFD-117501
GBFD-117501
MRFD-210301
MRFD-210305
GBFD-111003
GBFD-111003
GBFD-118603
GBFD-118630
GBFD-110607
GBFD-114301
GBFD-114302
GBFD-114301
GBFD-114302
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
GBFD-119115
GBFD-114301
GBFD-114302
GBFD-114301
GBFD-114302
GBFD-111101
GBFD-114101
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
MRFD-210301
MRFD-210301
MRFD-211402
MRFD-210301
MRFD-210301
GBFD-111202
GBFD-510901
MRFD-210301
MRFD-210301
MRFD-210602
GBFD-114402
GBFD-110601
GBFD-510501
MRFD-210301
GBFD-111804
GBFD-113001
MRFD-210301
MRFD-211402
GBFD-111202
MRFD-210301
GBFD-118701
GBFD-110801
GBFD-110802
GBFD-110801
GBFD-110802
GBFD-111003
GBFD-111202
GBFD-111202
GBFD-116201
GBFD-116201
GBFD-510803
GBFD-510804
GBFD-114325
MRFD-210304
MRFD-210304
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-110801
GBFD-110802
GBFD-110801
GBFD-110802
GBFD-111705
MRFD-210305
GBFD-111202
GBFD-118605
GBFD-510701
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111203
MRFD-210305
GBFD-111203
MRFD-210305
GBFD-111203
MRFD-210305
GBFD-111203
GBFD-111203
GBFD-510601
GBFD-111203
MRFD-210305
GBFD-114101
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-510103
GBFD-111202
GBFD-111005
None
GBFD-111203
GBFD-111203
GBFD-113602
GBFD-111005
GBFD-111804
None
GBFD-118605
MRFD-210206
GBFD-111202
MRFD-210601
GBFD-111202
MRFD-210601
GBFD-118609
GBFD-118609
GBFD-111202
GBFD-111202
GBFD-118602
GBFD-118602
GBFD-118602
GBFD-118609
GBFD-111207
MRFD-210301
GBFD-111203
MRFD-210301
GBFD-111207
MRFD-210301
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111005
None
GBFD-111705
GBFD-111705
GBFD-111705
MRFD-210301
MRFD-210301
MRFD-210301
GBFD-111803
GBFD-111203
GBFD-119301
GBFD-119301
GBFD-119301
GBFD-119301
GBFD-119301
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-118605
GBFD-111005
GBFD-111202
GBFD-111202
GBFD-119403
GBFD-110501
GBFD-118611
GBFD-118622
GBFD-111202
GBFD-111202
MRFD-210502
MRFD-210501
GBFD-111202
MRFD-210304
GBFD-111202
GBFD-111203
MRFD-210305
GBFD-111203
MRFD-210305
GBFD-111203
MRFD-210301
GBFD-111202
GBFD-118609
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-113725
GBFD-117401
GBFD-119701
GBFD-117401
MRFD-210403
GBFD-113725
MRFD-210304
GBFD-111202
GBFD-111202
GBFD-111203
MRFD-210305
MRFD-210304
MRFD-210304
GBFD-110601
GBFD-510501
GBFD-113602
GBFD-111202
GBFD-118201
GBFD-117602
GBFD-111003
GBFD-110301
MRFD-210305
GBFD-111202
GBFD-110601
GBFD-510501
GBFD-111202
MRFD-211503
None
None
None
None
MRFD-211503
MRFD-211503
None
None
None
None
MRFD-211503
GBFD-110601
GBFD-510501
MRFD-210206
MRFD-210301
GBFD-111203
MRFD-210305
MRFD-211402
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
MRFD-211503
MRFD-211503
GBFD-111207
GBFD-111602
MRFD-210301
GBFD-111202
GBFD-110402
GBFD-110301
MRFD-210305
MRFD-210305
GBFD-510301
GBFD-510302
GBFD-510301
GBFD-510302
GBFD-110402
GBFD-111203
GBFD-118602
GBFD-118622
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-111705
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111705
GBFD-111203
GBFD-118605
GBFD-111203
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-111705
None
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111705
GBFD-111705
GBFD-118201
GBFD-114101
GBFD-111202
MRFD-210602
MRFD-210602
MRFD-210602
MRFD-210602
GBFD-118605
GBFD-111202
GBFD-111202
MRFD-210301
GBFD-111804
GBFD-111202
None
MRFD-210401
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110204
GBFD-119405
GBFD-111203
MRFD-210305
GBFD-111203
GBFD-111602
GBFD-111202
GBFD-111202
GBFD-114501
GBFD-114402
GBFD-114402
GBFD-114402
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
MRFD-210304
MRFD-210304
GBFD-111202
GBFD-113101
GBFD-110501
GBFD-118602
GBFD-118622
GBFD-111203
MRFD-210305
GBFD-111202
None
None
None
None
GBFD-510701
GBFD-111202
MRFD-211402
MRFD-211402
MRFD-211402
MRFD-210301
GBFD-111203
GBFD-118609
GBFD-111202
MRFD-210602
MRFD-210602
None
None
GBFD-114301
GBFD-114302
GBFD-111202
GBFD-111202
GBFD-117401
GBFD-111203
MRFD-210305
MRFD-210502
GBFD-118611
GBFD-118622
None
GBFD-111202
GBFD-110608
GBFD-111005
GBFD-111203
GBFD-111203
GBFD-111203
MRFD-210403
GBFD-111202
GBFD-110607
GBFD-110607
GBFD-110601
GBFD-110601
GBFD-510501
GBFD-114301
GBFD-510804
GBFD-510804
GBFD-114201
GBFD-115902
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-510002
GBFD-119501
GBFD-510802
GBFD-110601
GBFD-510501
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-114101
GBFD-117601
GBFD-117601
GBFD-115501
GBFD-115501
GBFD-115501
GBFD-115502
GBFD-115502
GBFD-115502
GBFD-115507
GBFD-115507
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-511103
GBFD-110703
GBFD-115506
GBFD-115506
GBFD-115506
GBFD-115506
GBFD-117601
GBFD-117601
GBFD-511103
GBFD-110703
GBFD-110703
GBFD-110703
GBFD-110703
GBFD-110703
GBFD-110703
GBFD-110601
GBFD-510501
GBFD-115501
GBFD-510501
GBFD-115502
GBFD-510501
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-110703
GBFD-110703
GBFD-119203
GBFD-510301
GBFD-510302
GBFD-510301
GBFD-510302
GBFD-115501
GBFD-115501
GBFD-115501
GBFD-115502
GBFD-115502
GBFD-115502
GBFD-115507
GBFD-115507
GBFD-111202
GBFD-111202
GBFD-118620
GBFD-119106
GBFD-114201
GBFD-119106
GBFD-510804
GBFD-510804
GBFD-114101
GBFD-119106
GBFD-114201
GBFD-119106
GBFD-110703
GBFD-117601
GBFD-110203
GBFD-114101
GBFD-119106
GBFD-118901
GBFD-119106
GBFD-118901
GBFD-119106
GBFD-119106
GBFD-118901
GBFD-119106
GBFD-118901
GBFD-119106
MRFD-210304
GBFD-117602
GBFD-111804
GBFD-111806
GBFD-111804
GBFD-111803
GBFD-111803
GBFD-117401
GBFD-111804
GBFD-111806
GBFD-111804
GBFD-118602
MRFD-211402
GBFD-110601
GBFD-510501
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
None
MRFD-211503
MRFD-211503
MRFD-211503
MRFD-211503
MRFD-211503
GBFD-111605
GBFD-111605
GBFD-111605
GBFD-113602
GBFD-114802
GBFD-111202
None
GBFD-118611
GBFD-118622
GBFD-118602
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-118605
GBFD-114101
MRFD-210301
MRFD-210301
MRFD-210304
MRFD-210301
GBFD-114101
GBFD-114101
GBFD-116101
MRFD-210301
GBFD-111202
None
GBFD-118609
GBFD-118601
None
GBFD-118601
None
None
GBFD-110607
GBFD-510301
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-113521
GBFD-118601
GBFD-111207
GBFD-111207
GBFD-111207
GBFD-111207
GBFD-114101
GBFD-113101
GBFD-118201
GBFD-111202
GBFD-111203
GBFD-111202
GBFD-113101
GBFD-114101
GBFD-113101
GBFD-114101
GBFD-113101
GBFD-111602
GBFD-118101
GBFD-111202
GBFD-111202
GBFD-118401
GBFD-111207
None
MRFD-210501
MRFD-211501
MRFD-210501
GBFD-118605
GBFD-114301
GBFD-114301
GBFD-111101
MRFD-210304
GBFD-111203
MRFD-210304
MRFD-210304
GBFD-111202
GBFD-116101
MRFD-210301
GBFD-114402
GBFD-114402
GBFD-114402
GBFD-114201
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-111202
GBFD-119201
GBFD-510803
GBFD-510804
GBFD-116201
GBFD-116201
GBFD-116101
MRFD-210301
GBFD-110202
GBFD-110521
GBFD-111804
None
GBFD-118611
GBFD-118622
GBFD-115001
GBFD-510307
GBFD-115001
GBFD-118611
GBFD-118622
GBFD-118605
GBFD-111202
GBFD-116101
MRFD-210301
GBFD-111202
GBFD-510309
GBFD-111202
GBFD-113501
GBFD-113503
GBFD-111203
GBFD-111203
GBFD-116401
MRFD-210304
GBFD-111803
GBFD-111203
GBFD-111602
GBFD-111202
GBFD-111602
GBFD-111202
GBFD-111602
GBFD-111801
GBFD-111803
GBFD-111202
GBFD-111203
GBFD-111203
GBFD-113201
MRFD-211503
GBFD-113201
GBFD-113201
GBFD-113201
GBFD-113201
GBFD-118605
GBFD-118605
GBFD-113201
GBFD-113402
GBFD-118602
GBFD-118622
GBFD-118602
GBFD-113201
GBFD-115704
GBFD-111203
MRFD-210305
GBFD-110202
GBFD-118630
GBFD-118630
None
None
GBFD-118605
GBFD-111202
MRFD-210304
GBFD-110502
GBFD-115403
GBFD-117802
GBFD-116101
MRFD-210301
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
MRFD-210305
MRFD-210304
MRFD-210304
GBFD-113602
GBFD-111203
MRFD-210305
GBFD-111202
GBFD-111203
MRFD-210305
GBFD-111203
MRFD-210305
GBFD-116101
MRFD-210301
GBFD-116101
MRFD-210301
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-114101
GBFD-111203
GBFD-117602
GBFD-117602
MRFD-210301
GBFD-111202
MRFD-210301
GBFD-111202
MRFD-210301
MRFD-210301
GBFD-114001
GBFD-111202
GBFD-110801
GBFD-110802
GBFD-110801
GBFD-110802
GBFD-110801
GBFD-110802
GBFD-114001
GBFD-119203
GBFD-510301
GBFD-510302
GBFD-510307
GBFD-510307
GBFD-111202
GBFD-111005
GBFD-110601
GBFD-510501
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
GBFD-110502
GBFD-117802
GBFD-111203
None
GBFD-118601
GBFD-111705
None
None
GBFD-118611
GBFD-118622
None
None
MRFD-211503
None
GBFD-510701
GBFD-111202
GBFD-111705
MRFD-210103
GBFD-111202
GBFD-111705
GBFD-111202
GBFD-114301
MRFD-210301
GBFD-114301
GBFD-114301
GBFD-114301
GBFD-114301
GBFD-114301
GBFD-114301
GBFD-114301
GBFD-114301
GBFD-114301
GBFD-114301
GBFD-110801
GBFD-114301
GBFD-114301
GBFD-114301
GBFD-111705
GBFD-116801
GBFD-116801
GBFD-116801
GBFD-116801
GBFD-116801
GBFD-116801
GBFD-116801
GBFD-116801
GBFD-113701
GBFD-111203
MRFD-210305
GBFD-111203
MRFD-210401
GBFD-111203
MRFD-210305
MRFD-210301
GBFD-111203
MRFD-210304
GBFD-116201
GBFD-111203
MRFD-210305
GBFD-117601
GBFD-111202
GBFD-117301
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-117301
GBFD-117001
GBFD-113521
GBFD-118201
GBFD-119501
GBFD-119501
None
None
None
GBFD-118611
GBFD-118622
None
GBFD-118605
MRFD-211503
GBFD-110601
GBFD-110601
GBFD-110601
GBFD-110601
GBFD-110601
GBFD-110601
GBFD-110601
GBFD-110601
GBFD-110601
GBFD-114101
GBFD-111003
GBFD-111101
GBFD-111202
MRFD-210303
GBFD-111203
MRFD-210401
GBFD-111203
MRFD-210301
MRFD-210403
GBFD-111202
GBFD-111202
GBFD-113101
GBFD-114201
GBFD-111804
GBFD-115601
GBFD-114101
GBFD-110501
GBFD-113301
GBFD-110601
GBFD-510501
GBFD-111202
GBFD-111202
None
GBFD-510702
GBFD-510607
GBFD-510601
GBFD-510701
GBFD-118604
GBFD-118610
GBFD-118201
MRFD-210301
GBFD-114801
GBFD-115501
GBFD-111203
MRFD-210305
GBFD-111203
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-110101
GBFD-510101
GBFD-510101
MRFD-210301
GBFD-111005
GBFD-112401
MRFD-210301
GBFD-510901
GBFD-112401
GBFD-110601
GBFD-510501
GBFD-114803
GBFD-115501
GBFD-510701
GBFD-111202
GBFD-510701
GBFD-111202
GBFD-111203
MRFD-210305
GBFD-118605
GBFD-118605
None
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-511103
GBFD-511103
GBFD-118602
GBFD-119115
GBFD-118201
GBFD-118201
GBFD-118201
GBFD-118201
GBFD-119901
GBFD-510301
GBFD-510302
MRFD-210502
GBFD-510301
GBFD-510302
GBFD-510307
None
GBFD-114101
GBFD-111101
GBFD-114101
GBFD-114101
GBFD-114101
GBFD-114201
GBFD-114101
GBFD-114101
GBFD-116201
GBFD-114101
GBFD-510401
MRFD-210501
MRFD-210502
GBFD-116001
GBFD-510309
GBFD-510309
GBFD-113725
GBFD-113725
GBFD-117301
GBFD-118605
GBFD-118605
GBFD-113602
GBFD-118605
GBFD-118605
GBFD-114401
GBFD-114302
GBFD-111202
GBFD-118601
GBFD-118601
GBFD-113401
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-111202
MRFD-210601
GBFD-111202
MRFD-210601
GBFD-118602
GBFD-111202
GBFD-510501
GBFD-510501
GBFD-111202
GBFD-111202
GBFD-110101
GBFD-115001
GBFD-115001
GBFD-115001
GBFD-111202
GBFD-111005
MRFD-210305
GBFD-119404
GBFD-113201
GBFD-118701
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-111203
GBFD-111203
GBFD-110601
GBFD-510103
GBFD-510103
GBFD-510103
GBFD-510102
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-114301
GBFD-114302
GBFD-510102
GBFD-111203
GBFD-110601
GBFD-510501
GBFD-113201
GBFD-110601
GBFD-510501
GBFD-114402
GBFD-113701
GBFD-117002
GBFD-113701
GBFD-117101
GBFD-110601
GBFD-510501
GBFD-113701
GBFD-113703
GBFD-113703
GBFD-113701
GBFD-110601
GBFD-510501
GBFD-118201
GBFD-114301
GBFD-114302
GBFD-111804
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-510102
GBFD-113725
GBFD-113725
GBFD-110601
GBFD-510501
GBFD-510102
GBFD-113703
GBFD-113703
GBFD-111202
GBFD-116001
GBFD-111202
GBFD-111601
GBFD-111202
GBFD-111601
GBFD-113401
GBFD-111101
GBFD-114801
GBFD-113401
GBFD-113201
GBFD-114803
GBFD-113401
GBFD-113701
GBFD-111202
GBFD-117001
GBFD-111202
GBFD-118609
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-111202
GBFD-111804
GBFD-111207
GBFD-111202
GBFD-111202
GBFD-111804
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-111604
GBFD-111202
GBFD-118605
GBFD-118603
GBFD-118603
GBFD-118603
GBFD-111203
GBFD-111203
GBFD-111202
GBFD-118602
None
GBFD-113001
GBFD-111202
None
MRFD-210301
MRFD-210301
MRFD-211402
MRFD-210301
GBFD-111202
GBFD-111202
GBFD-114701
MRFD-210301
GBFD-111203
GBFD-113601
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-510102
GBFD-111203
GBFD-111804
GBFD-110502
GBFD-119202
GBFD-110502
GBFD-110502
GBFD-110502
GBFD-110502
GBFD-113201
GBFD-113201
GBFD-118201
GBFD-110502
GBFD-111203
GBFD-114101
GBFD-110601
GBFD-510501
GBFD-118201
GBFD-118201
GBFD-115402
GBFD-111202
GBFD-111202
GBFD-115504
GBFD-115504
MRFD-211402
MRFD-210304
GBFD-115504
GBFD-115504
GBFD-111005
GBFD-115501
GBFD-115502
GBFD-115507
GBFD-114701
GBFD-114402
GBFD-114402
MRFD-210301
MRFD-210301
GBFD-114402
GBFD-114402
GBFD-114402
GBFD-114402
GBFD-114701
GBFD-111202
GBFD-111203
GBFD-115402
GBFD-110608
GBFD-114701
GBFD-111202
GBFD-114701
GBFD-111202
GBFD-113602
GBFD-110601
GBFD-510501
GBFD-112401
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-111005
GBFD-111001
GBFD-111005
GBFD-111001
GBFD-111005
GBFD-111001
GBFD-111005
GBFD-111001
GBFD-111005
GBFD-111001
GBFD-111005
GBFD-111001
GBFD-111005
GBFD-118201
GBFD-111005
GBFD-511104
GBFD-511103
GBFD-114301
GBFD-114302
MRFD-211404
GBFD-511103
GBFD-511103
GBFD-511103
GBFD-511103
GBFD-511103
GBFD-511103
GBFD-114301
GBFD-114302
GBFD-511103
GBFD-111203
MRFD-210305
None
GBFD-110801
GBFD-110802
GBFD-114402
GBFD-110601
GBFD-110601
GBFD-510501
GBFD-115504
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
MRFD-211402
GBFD-511103
GBFD-511103
GBFD-511103
GBFD-114701
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-117501
MRFD-210301
GBFD-111203
MRFD-210403
GBFD-118603
GBFD-118603
GBFD-118601
GBFD-111202
GBFD-118605
GBFD-118611
GBFD-118622
MRFD-211502
None
None
None
GBFD-118603
GBFD-118603
GBFD-118606
GBFD-118603
GBFD-118606
GBFD-118603
GBFD-118603
GBFD-118630
GBFD-118630
GBFD-118611
GBFD-118622
MRFD-210103
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
None
GBFD-118601
GBFD-118601
GBFD-111202
GBFD-118201
GBFD-510103
GBFD-118606
GBFD-118606
GBFD-117801
GBFD-111202
GBFD-114201
GBFD-118605
GBFD-114101
MRFD-210301
GBFD-113726
GBFD-510104
GBFD-116201
GBFD-118603
None
GBFD-118201
GBFD-111202
GBFD-117803
GBFD-117702
GBFD-113726
MRFD-210301
MRFD-210301
GBFD-111202
GBFD-111202
GBFD-117804
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
GBFD-118605
GBFD-118605
GBFD-113201
GBFD-113101
GBFD-113201
GBFD-113201
GBFD-113201
GBFD-113201
GBFD-114402
GBFD-118630
GBFD-118604
GBFD-118610
None
None
None
None
None
None
None
None
None
None
None
None
None
None
GBFD-118401
GBFD-111612
GBFD-118601
None
GBFD-110601
GBFD-510501
None
MRFD-210301
GBFD-510702
GBFD-111701
GBFD-115402
GBFD-115402
GBFD-115402
GBFD-115402
GBFD-115402
GBFD-115402
MRFD-210502
MRFD-210502
MRFD-210103
None
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
None
None
GBFD-118601
GBFD-117301
GBFD-118601
GBFD-117301
GBFD-118601
GBFD-117301
GBFD-118602
GBFD-118622
GBFD-111203
MRFD-210305
GBFD-111203
None
GBFD-118605
GBFD-110801
GBFD-110802
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
MRFD-210301
MRFD-210301
GBFD-118611
GBFD-118622
MRFD-210301
GBFD-111203
GBFD-111202
MRFD-210304
MRFD-210304
GBFD-111203
None
GBFD-111804
MRFD-210304
MRFD-210301
GBFD-118611
GBFD-118622
GBFD-111202
GBFD-111202
None
GBFD-114701
GBFD-118602
GBFD-118622
GBFD-111804
GBFD-118602
GBFD-110601
GBFD-510501
GBFD-117401
GBFD-116201
GBFD-111202
GBFD-110601
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-110601
GBFD-510501
GBFD-111202
GBFD-116201
GBFD-116201
GBFD-116201
GBFD-114301
GBFD-116201
GBFD-111005
GBFD-110601
None
GBFD-113725
None
GBFD-111202
GBFD-118611
GBFD-118611
GBFD-118603
GBFD-118603
GBFD-510104
GBFD-510104
MRFD-210304
GBFD-118602
GBFD-118622
GBFD-118602
GBFD-118622
GBFD-111203
MRFD-210305
GBFD-118602
GBFD-118622
MRFD-210301
GBFD-111202
GBFD-111705
GBFD-111705
None
None
None
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111203
GBFD-111202
GBFD-115402
GBFD-115402
GBFD-115402
GBFD-115402
GBFD-115402
GBFD-115402
MRFD-210502
MRFD-210502
MRFD-210301
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-111203
GBFD-117002
GBFD-111203
GBFD-111203
None
None
GBFD-111203
None
GBFD-117301
GBFD-117301
GBFD-111202
GBFD-113201
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-118605
None
None
GBFD-118605
None
GBFD-114201
GBFD-111202
GBFD-111202
GBFD-118601
GBFD-117301
GBFD-111203
MRFD-210305
MRFD-210301
MRFD-210301
MRFD-210401
GBFD-111203
MRFD-210305
GBFD-111203
MRFD-210305
GBFD-111202
GBFD-111202
GBFD-115506
GBFD-115506
GBFD-115506
GBFD-115506
GBFD-119301
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111601
GBFD-118602
MRFD-210301
GBFD-118630
GBFD-118630
GBFD-113701
None
GBFD-111609
GBFD-111609
GBFD-111609
GBFD-111609
GBFD-111609
GBFD-118630
GBFD-118601
GBFD-510104
MRFD-210206
GBFD-111202
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
GBFD-117002
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
GBFD-111202
GBFD-118630
MRFD-210301
None
GBFD-118611
GBFD-118622
GBFD-118630
None
None
GBFD-113601
GBFD-118601
GBFD-118611
GBFD-118611
GBFD-118606
GBFD-118606
GBFD-110703
GBFD-118602
GBFD-118609
MRFD-210103
GBFD-110601
GBFD-510501
GBFD-114101
GBFD-114101
GBFD-111605
GBFD-510701
GBFD-510601
GBFD-510702
GBFD-118605
GBFD-111202
GBFD-118604
GBFD-118610
GBFD-118611
GBFD-118622
MRFD-210305
MRFD-210304
GBFD-111202
GBFD-118602
GBFD-114101
GBFD-113101
GBFD-114101
GBFD-113101
GBFD-114101
MRFD-210305
GBFD-111202
GBFD-111202
GBFD-110601
GBFD-510501
GBFD-119110
GBFD-119110
GBFD-119110
GBFD-119110
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-110703
GBFD-110703
GBFD-110703
GBFD-110901
GBFD-114001
GBFD-111004
GBFD-111004
GBFD-111004
MRFD-210502
GBFD-117301
None
GBFD-110703
MRFD-210305
None
GBFD-118609
GBFD-114401
GBFD-111101
GBFD-117501
GBFD-117501
GBFD-118201
GBFD-118201
MRFD-210301
GBFD-510702
None
GBFD-118611
MRFD-210301
GBFD-111202
GBFD-111202
GBFD-111005
GBFD-111202
None
GBFD-118630
MRFD-210301
GBFD-118630
GBFD-118630
MRFD-210301
GBFD-119102
GBFD-511103
GBFD-117501
GBFD-110801
GBFD-118630
GBFD-118630
MRFD-210301
GBFD-118630
GBFD-118630
GBFD-118611
GBFD-116201
GBFD-118611
GBFD-118622
GBFD-114301
GBFD-110601
GBFD-510501
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
GBFD-110607
GBFD-113001
GBFD-114301
GBFD-114302
None
GBFD-118609
GBFD-118609
GBFD-118609
GBFD-118609
None
None
MRFD-210301
GBFD-510702
GBFD-111705
MRFD-210502
GBFD-118602
GBFD-118622
MRFD-210301
MRFD-210301
None
None
GBFD-111701
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
GBFD-111202
GBFD-111211
GBFD-111202
GBFD-111211
GBFD-111202
GBFD-510102
GBFD-118611
GBFD-118611
GBFD-118611
GBFD-118622
None
GBFD-118611
GBFD-111301
GBFD-111202
GBFD-118611
GBFD-118611
GBFD-118622
MRFD-210301
MRFD-210301
GBFD-110703
GBFD-110601
GBFD-510501
GBFD-117601
GBFD-110802
GBFD-111202
GBFD-111202
GBFD-111203
GBFD-111203
GBFD-118601
GBFD-118201
GBFD-110501
GBFD-117401
GBFD-117401
GBFD-117401
GBFD-117401
GBFD-117401
GBFD-111804
GBFD-110503
GBFD-111203
GBFD-117701
GBFD-117702
GBFD-117701
GBFD-117702
GBFD-117701
GBFD-117702
GBFD-117701
GBFD-117702
GBFD-117701
GBFD-117702
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117701
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-117702
GBFD-510102
GBFD-111003
GBFD-110301
GBFD-111701
GBFD-510801
GBFD-510801
GBFD-111202
GBFD-110601
GBFD-510501
GBFD-116201
GBFD-119001
GBFD-113725
GBFD-114101
None
GBFD-111705
None
GBFD-111804
None
GBFD-118602
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-111202
GBFD-114101
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-118611
GBFD-118622
None
GBFD-118604
GBFD-118610
GBFD-111202
GBFD-118604
GBFD-118610
GBFD-117801
GBFD-111002
GBFD-111002
GBFD-111002
GBFD-111002
GBFD-111002
GBFD-111002
GBFD-111002
GBFD-114101
GBFD-114101
GBFD-114101
GBFD-119205
GBFD-510002
GBFD-510002
GBFD-510002
GBFD-116301
GBFD-119502
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-118605
GBFD-118602
GBFD-118602
GBFD-118602
GBFD-118602
GBFD-118602
GBFD-114101
GBFD-111005
GBFD-119115
GBFD-115501
GBFD-115502
MRFD-210301
GBFD-117002
MRFD-210301
GBFD-117002
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
GBFD-510704
GBFD-510601
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
GBFD-116201
GBFD-116301
GBFD-116201
GBFD-116201
GBFD-119502
MRFD-210301
MRFD-210301
GBFD-110401
GBFD-110402
GBFD-110801
GBFD-110802
GBFD-510102
GBFD-110601
GBFD-510501
GBFD-510901
GBFD-510901
GBFD-510901
GBFD-510901
GBFD-510901
GBFD-510901
GBFD-510901
GBFD-510901
GBFD-510301
GBFD-510302
GBFD-510301
GBFD-510302
GBFD-119107
GBFD-114302
GBFD-111804
MRFD-210301
GBFD-110601
GBFD-510501
None
None
None
GBFD-118611
GBFD-111804
MRFD-210401
GBFD-119108
GBFD-114151
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-510501
GBFD-116902
GBFD-118605
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-111202
GBFD-117601
GBFD-119107
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
GBFD-116201
GBFD-111202
GBFD-111705
GBFD-111004
GBFD-510309
None
GBFD-117501
GBFD-117501
GBFD-117401
GBFD-119701
GBFD-119701
GBFD-111101
GBFD-119001
GBFD-119001
GBFD-110601
GBFD-510501
GBFD-115402
GBFD-118201
GBFD-510002
GBFD-510002
GBFD-111202
GBFD-111202
GBFD-510301
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-118605
GBFD-111202
GBFD-111202
MRFD-210103
GBFD-111202
GBFD-111202
MRFD-210103
MRFD-210602
GBFD-111207
GBFD-111203
None
MRFD-210304
MRFD-210304
MRFD-210301
GBFD-119901
GBFD-113201
GBFD-113728
GBFD-111202
GBFD-116601
GBFD-111202
GBFD-111202
GBFD-111202
None
GBFD-118605
GBFD-111202
GBFD-118601
GBFD-111202
GBFD-111202
GBFD-111203
MRFD-210305
MRFD-210301
GBFD-118701
GBFD-111202
GBFD-111803
GBFD-118701
GBFD-118701
GBFD-118701
MRFD-210401
GBFD-111803
GBFD-111801
GBFD-111803
GBFD-111203
GBFD-118701
GBFD-113201
GBFD-113201
GBFD-113201
GBFD-111005
GBFD-111202
GBFD-111202
GBFD-111202
MRFD-211402
MRFD-211501
MRFD-210401
GBFD-110101
GBFD-114201
GBFD-113201
GBFD-114402
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-114402
GBFD-111005
GBFD-114402
GBFD-114402
GBFD-114402
GBFD-114402
GBFD-114402
GBFD-114402
GBFD-114701
GBFD-114701
GBFD-111203
GBFD-111203
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-510104
GBFD-510104
GBFD-510104
GBFD-114402
GBFD-111202
GBFD-114701
GBFD-111203
GBFD-114701
GBFD-511103
GBFD-114321
GBFD-114321
MRFD-211402
GBFD-114701
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
GBFD-111003
GBFD-111202
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111612
GBFD-119202
GBFD-111705
GBFD-110303
GBFD-111705
GBFD-110303
GBFD-114101
GBFD-114101
GBFD-114101
GBFD-111602
GBFD-111202
GBFD-111202
GBFD-118605
GBFD-118601
GBFD-118602
None
GBFD-117602
GBFD-510501
GBFD-118601
GBFD-118602
MRFD-210401
GBFD-119115
GBFD-110601
GBFD-110601
GBFD-110601
GBFD-110601
GBFD-114101
GBFD-110703
GBFD-119115
GBFD-111203
GBFD-114101
GBFD-111203
GBFD-114101
GBFD-111202
GBFD-117301
GBFD-114101
GBFD-113101
GBFD-111606
GBFD-113101
GBFD-119303
GBFD-114101
GBFD-113101
GBFD-118602
GBFD-118622
GBFD-113725
GBFD-118601
GBFD-118601
GBFD-113725
GBFD-118601
GBFD-113725
GBFD-118601
GBFD-113725
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-118609
GBFD-118611
GBFD-118611
GBFD-118602
GBFD-118622
GBFD-118602
GBFD-118622
GBFD-118605
GBFD-118601
GBFD-118602
GBFD-118602
GBFD-118622
GBFD-111202
GBFD-110601
GBFD-510501
GBFD-116201
GBFD-116201
GBFD-110601
GBFD-510501
GBFD-118605
GBFD-510901
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-119901
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-118605
GBFD-118604
GBFD-118610
GBFD-110402
GBFD-111101
MRFD-210305
GBFD-118630
GBFD-118630
None
GBFD-118604
GBFD-119801
None
GBFD-118630
GBFD-119110
GBFD-114201
GBFD-119110
GBFD-119110
GBFD-114201
GBFD-119110
GBFD-114201
GBFD-118605
GBFD-118605
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111705
GBFD-111705
GBFD-110303
GBFD-110303
GBFD-110303
GBFD-111705
GBFD-111705
GBFD-111705
MRFD-210301
MRFD-210304
MRFD-210301
GBFD-111801
GBFD-111803
None
GBFD-111203
MRFD-210304
None
None
None
None
None
GBFD-111701
None
None
None
None
GBFD-118609
None
None
GBFD-510002
GBFD-111203
GBFD-111202
MRFD-210304
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-119905
GBFD-119905
GBFD-119905
GBFD-119905
GBFD-111202
GBFD-111202
MRFD-210301
MRFD-210301
GBFD-111203
GBFD-117801
GBFD-113728
GBFD-111203
GBFD-111203
None
MRFD-210301
GBFD-118630
MRFD-211501
GBFD-114323
GBFD-111202
GBFD-111202
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-111202
GBFD-510804
GBFD-510804
GBFD-111202
GBFD-111202
MRFD-210301
MRFD-210301
GBFD-118611
GBFD-118611
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
None
GBFD-118611
GBFD-118611
GBFD-118622
None
GBFD-115001
GBFD-115001
GBFD-110202
GBFD-110521
GBFD-110802
GBFD-118601
GBFD-111101
GBFD-114101
GBFD-111705
GBFD-110802
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-117301
GBFD-114101
GBFD-111804
GBFD-118602
GBFD-111804
GBFD-118602
None
GBFD-118601
GBFD-118601
GBFD-118601
MRFD-210305
GBFD-118601
GBFD-111804
GBFD-510002
GBFD-111202
GBFD-111610
GBFD-111602
None
None
None
None
None
None
None
None
GBFD-118605
GBFD-118605
GBFD-119502
None
None
GBFD-111705
GBFD-111101
GBFD-119102
GBFD-119102
GBFD-118605
GBFD-118605
GBFD-111705
GBFD-113201
None
GBFD-111003
GBFD-510104
None
GBFD-111705
GBFD-111705
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-113201
GBFD-111608
None
MRFD-210304
GBFD-111203
GBFD-110402
GBFD-119001
MRFD-210304
None
None
None
None
GBFD-118401
None
GBFD-111202
MRFD-210305
GBFD-111202
GBFD-111202
GBFD-510002
MRFD-210305
GBFD-111203
MRFD-210305
GBFD-111202
MRFD-210305
GBFD-111202
MRFD-210304
MRFD-210304
GBFD-117602
GBFD-117601
GBFD-110703
GBFD-111003
GBFD-111003
GBFD-510104
GBFD-111202
GBFD-111605
GBFD-111005
MRFD-210301
GBFD-111202
MRFD-210601
GBFD-111202
MRFD-210601
GBFD-111202
None
None
None
None
None
GBFD-114301
GBFD-114302
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-114301
GBFD-114302
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-119902
GBFD-114301
GBFD-114302
GBFD-114301
GBFD-114302
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-111005
GBFD-111202
GBFD-111202
GBFD-110703
GBFD-110601
GBFD-510501
GBFD-510102
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
MRFD-210301
MRFD-210301
GBFD-114101
GBFD-510701
GBFD-510701
GBFD-510702
GBFD-111003
GBFD-111003
GBFD-111003
GBFD-510104
GBFD-111101
GBFD-114101
GBFD-114101
GBFD-111003
GBFD-114101
GBFD-118601
GBFD-115506
GBFD-115507
GBFD-115506
GBFD-115701
GBFD-110801
MRFD-210301
GBFD-111203
GBFD-111202
GBFD-111202
GBFD-111202
MRFD-210301
GBFD-118605
GBFD-112501
GBFD-112501
GBFD-113201
GBFD-115501
GBFD-113201
GBFD-115502
GBFD-113201
GBFD-113201
GBFD-113201
GBFD-111705
GBFD-118605
GBFD-113201
GBFD-113201
MRFD-210301
GBFD-111705
GBFD-111705
MRFD-210502
MRFD-210502
MRFD-210502
MRFD-210502
MRFD-210502
MRFD-210502
MRFD-210502
GBFD-117702
GBFD-113725
GBFD-113725
GBFD-113725
GBFD-118201
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-118605
None
GBFD-118603
GBFD-113602
GBFD-113721
GBFD-113721
GBFD-113721
MRFD-210304
GBFD-111203
GBFD-116201
GBFD-116201
GBFD-116201
GBFD-116201
GBFD-113101
GBFD-111602
GBFD-111202
GBFD-111202
MRFD-210305
GBFD-114101
GBFD-111612
GBFD-114101
GBFD-119001
GBFD-111804
GBFD-111203
MRFD-210403
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
MRFD-210304
MRFD-211402
GBFD-116001
MRFD-210301
GBFD-111004
GBFD-111101
GBFD-111203
GBFD-119301
GBFD-510401
GBFD-116301
None
GBFD-111004
GBFD-116902
MRFD-210301
MRFD-211402
MRFD-211402
MRFD-211402
MRFD-210305
GBFD-118603
GBFD-118603
GBFD-116801
GBFD-119107
GBFD-119107
GBFD-114302
GBFD-118605
GBFD-116801
GBFD-117501
GBFD-117501
GBFD-118605
None
GBFD-118605
GBFD-110601
GBFD-510501
GBFD-114301
GBFD-114302
GBFD-114301
GBFD-114302
None
None
GBFD-114101
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-118601
MRFD-210301
GBFD-510901
MRFD-210401
GBFD-111203
GBFD-111804
GBFD-118611
GBFD-110202
None
None
None
None
None
None
None
None
None
None
GBFD-111602
GBFD-111701
GBFD-118602
GBFD-118622
GBFD-118602
GBFD-118602
None
None
GBFD-118601
GBFD-118602
GBFD-118602
GBFD-118602
GBFD-118602
GBFD-118602
GBFD-115506
GBFD-510805
GBFD-119901
GBFD-118601
GBFD-118605
GBFD-118605
GBFD-111202
GBFD-118605
GBFD-118605
GBFD-114101
GBFD-115501
GBFD-510501
GBFD-111101
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
None
None
GBFD-112301
MRFD-210304
GBFD-111202
GBFD-510301
GBFD-118103
GBFD-118103
GBFD-118103
MRFD-210304
GBFD-111610
GBFD-111610
GBFD-111610
GBFD-111610
GBFD-111610
GBFD-111004
MRFD-210304
GBFD-112301
MRFD-210304
GBFD-112301
MRFD-210304
GBFD-111202
GBFD-111202
GBFD-118201
GBFD-118201
GBFD-117501
GBFD-118603
GBFD-510102
MRFD-210301
GBFD-111202
GBFD-113602
GBFD-111202
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-114301
GBFD-114302
MRFD-210304
GBFD-118602
GBFD-118622
GBFD-111203
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-111701
GBFD-111202
GBFD-116101
MRFD-210301
MRFD-210301
GBFD-110502
GBFD-110502
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-113001
GBFD-111701
GBFD-113503
GBFD-111605
GBFD-110601
GBFD-510501
GBFD-117601
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-118603
GBFD-111701
GBFD-111202
GBFD-111601
MRFD-210304
MRFD-210304
GBFD-111202
GBFD-117501
GBFD-111202
GBFD-111101
GBFD-116401
GBFD-110601
GBFD-510501
GBFD-111804
GBFD-110203
GBFD-510307
GBFD-510307
GBFD-111612
GBFD-111101
GBFD-111101
GBFD-111101
GBFD-111202
GBFD-111202
GBFD-111203
GBFD-111203
MRFD-210602
GBFD-111203
GBFD-118602
GBFD-113726
GBFD-118601
GBFD-510601
GBFD-111203
MRFD-210305
GBFD-118601
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-119701
MRFD-210301
GBFD-119701
GBFD-119701
GBFD-119701
GBFD-114101
GBFD-119701
GBFD-111705
GBFD-111203
GBFD-118701
MRFD-210304
GBFD-111605
GBFD-111101
GBFD-110601
GBFD-510501
GBFD-118201
GBFD-111804
GBFD-111804
GBFD-118602
GBFD-118603
GBFD-118603
GBFD-118605
GBFD-118201
GBFD-110601
GBFD-510501
GBFD-111804
GBFD-115301
GBFD-110601
GBFD-510501
GBFD-119303
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
None
None
GBFD-111203
GBFD-118201
GBFD-118606
GBFD-510104
GBFD-111207
GBFD-111804
GBFD-113725
GBFD-116101
MRFD-210301
None
None
MRFD-210304
GBFD-116101
MRFD-210301
WRFD-040100
MRFD-210301
MRFD-210301
None
GBFD-118602
None
None
GBFD-111203
MRFD-210304
MRFD-210304
None
None
MRFD-210301
MRFD-211402
GBFD-111202
GBFD-118609
MRFD-210301
GBFD-111203
GBFD-111202
GBFD-111202
GBFD-111202
MRFD-210301
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111203
GBFD-111802
GBFD-111804
GBFD-111802
GBFD-111804
GBFD-111802
GBFD-111804
GBFD-111203
GBFD-111804
GBFD-111003
GBFD-110301
MRFD-210304
MRFD-210304
GBFD-119301
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-510309
GBFD-510309
GBFD-510309
None
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-111101
GBFD-114802
GBFD-113601
MRFD-211402
MRFD-211402
GBFD-119502
GBFD-119502
GBFD-116301
GBFD-510301
GBFD-114101
GBFD-114101
GBFD-114101
GBFD-114101
GBFD-118701
GBFD-510805
GBFD-118701
GBFD-111203
GBFD-111804
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-110601
GBFD-510501
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
GBFD-111203
MRFD-210502
MRFD-210502
GBFD-110601
GBFD-510501
GBFD-118609
MRFD-210301
MRFD-210301
None
MRFD-210301
None
MRFD-210502
None
MRFD-210301
MRFD-210301
None
None
GBFD-118602
None
None
MRFD-210304
None
MRFD-210301
MRFD-211402
GBFD-111202
GBFD-118609
MRFD-210301
GBFD-111203
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111203
GBFD-111203
MRFD-210301
GBFD-111202
MRFD-210502
MRFD-210304
GBFD-118603
GBFD-118603
GBFD-111202
GBFD-117804
GBFD-118605
GBFD-110601
GBFD-510501
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
MRFD-210301
MRFD-211402
MRFD-210304
GBFD-110601
GBFD-510501
GBFD-116101
MRFD-210301
GBFD-111203
GBFD-111203
GBFD-111203
MRFD-210305
MRFD-210304
MRFD-210304
GBFD-113602
MRFD-210304
GBFD-113701
GBFD-111705
GBFD-111803
GBFD-111203
GBFD-111602
GBFD-111202
GBFD-111602
GBFD-111705
GBFD-111705
GBFD-111202
GBFD-510309
GBFD-111602
GBFD-111801
GBFD-111803
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111803
GBFD-111202
GBFD-111203
MRFD-210305
GBFD-510901
GBFD-111804
GBFD-111202
GBFD-115821
GBFD-113521
GBFD-510309
GBFD-111804
GBFD-114701
GBFD-112401
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111203
MRFD-210305
GBFD-111202
GBFD-111202
GBFD-113726
GBFD-113726
GBFD-111202
GBFD-118604
GBFD-118610
GBFD-118604
GBFD-111203
None
GBFD-117301
GBFD-117301
GBFD-111203
GBFD-111202
GBFD-111803
MRFD-210502
MRFD-210502
GBFD-113602
GBFD-113101
GBFD-119402
GBFD-114151
GBFD-113101
GBFD-119401
GBFD-114151
GBFD-117702
GBFD-115701
MRFD-211404
GBFD-119110
GBFD-118603
GBFD-118603
MRFD-210304
GBFD-111203
GBFD-111203
GBFD-111202
GBFD-111202
GBFD-116101
MRFD-210301
MRFD-210301
None
MRFD-210403
GBFD-118609
GBFD-111202
GBFD-115501
GBFD-115502
GBFD-118602
GBFD-118602
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111202
GBFD-111203
MRFD-210305
GBFD-116101
MRFD-210301
GBFD-118201
GBFD-114302
GBFD-117002
GBFD-118201
GBFD-118606
GBFD-118606
GBFD-118606
GBFD-118606
MRFD-210301
MRFD-210301
GBFD-110601
GBFD-510501
MRFD-210301
GBFD-510301
MRFD-210301
MRFD-210301
GBFD-119001
GBFD-118601
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-119001
GBFD-118601
GBFD-117801
GBFD-111002
GBFD-111002
GBFD-111002
GBFD-111002
GBFD-111002
GBFD-111002
GBFD-111002
GBFD-117802
GBFD-111804
GBFD-111804
GBFD-111804
GBFD-119001
GBFD-118601
GBFD-110601
GBFD-510501
GBFD-510302
GBFD-114101
GBFD-114101
GBFD-110301
GBFD-510002
GBFD-111804
GBFD-119001
GBFD-111804
GBFD-119001
GBFD-111804
GBFD-119001
GBFD-119001
GBFD-111804
GBFD-110601
GBFD-510501
GBFD-113201
GBFD-110601
GBFD-510501
GBFD-113201
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-510306
GBFD-110601
GBFD-510501
GBFD-118201
GBFD-510501
GBFD-113201
GBFD-119115
GBFD-119115
GBFD-111203
GBFD-111202
GBFD-113728
GBFD-117801
GBFD-111804
GBFD-119001
GBFD-111202
GBFD-111203
GBFD-113726
GBFD-113402
GBFD-111005
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-111004
GBFD-110601
GBFD-510501
GBFD-117601
GBFD-111005
GBFD-113521
GBFD-113521
GBFD-113201
GBFD-113201
GBFD-111804
GBFD-111804
GBFD-111203
GBFD-111202
None
GBFD-113726
None
None
MRFD-210301
GBFD-114302
MRFD-210301
GBFD-114302
GBFD-114302
GBFD-114302
GBFD-114302
GBFD-114302
GBFD-114302
GBFD-114302
GBFD-114302
GBFD-114302
MRFD-210301
GBFD-114302
GBFD-114302
GBFD-118605
GBFD-118605
GBFD-111203
GBFD-111203
GBFD-111203
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-111202
MRFD-210301
MRFD-210301
MRFD-210301
MRFD-210301
GBFD-111202
GBFD-111601
GBFD-111202
GBFD-111202
GBFD-111101
GBFD-119001
GBFD-113602
GBFD-115701
GBFD-111207
MRFD-210301
GBFD-111203
None
None
None
None
None
GBFD-114101
GBFD-111202
GBFD-111202
GBFD-119902
GBFD-119902
GBFD-119902
GBFD-119902
GBFD-119902
GBFD-119902
GBFD-119902
GBFD-119902
GBFD-119902
GBFD-118605
GBFD-119701
GBFD-118001
GBFD-118001
GBFD-118001
GBFD-118001
GBFD-118001
GBFD-118001
GBFD-118001
GBFD-117002
GBFD-117401
GBFD-111203
MRFD-210305
GBFD-111203
GBFD-112401
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-113201
GBFD-118630
GBFD-118630
GBFD-118630
GBFD-118630
GBFD-118604
GBFD-110601
GBFD-510501
None
GBFD-111606
GBFD-110601
GBFD-510501
GBFD-113201
GBFD-111005
GBFD-117401
GBFD-111203
MRFD-210305
GBFD-114101
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-111203
GBFD-118605
None
None
GBFD-111207
GBFD-110501
MRFD-210304
GBFD-111203
MRFD-210304
GBFD-111804
GBFD-111804
MRFD-210301
GBFD-113903
GBFD-111203
GBFD-116101
MRFD-210301
GBFD-110402
MRFD-211501
MRFD-211501
MRFD-211501
GBFD-111203
GBFD-111202
GBFD-110601
GBFD-510501
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-119501
GBFD-119501
GBFD-118602
GBFD-113901
GBFD-111203
GBFD-118605
GBFD-118605
GBFD-118605
GBFD-111202
GBFD-118601
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-114101
GBFD-110601
GBFD-510501
MRFD-210103
MRFD-210103
MRFD-210103
GBFD-111202
GBFD-118605
None
None
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-118605
None
GBFD-111202
None
GBFD-118609
GBFD-118630
GBFD-113801
GBFD-111207
GBFD-113701
MRFD-210301
GBFD-510104
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113703
GBFD-113701
GBFD-111207
GBFD-113701
MRFD-210301
GBFD-111202
GBFD-111202
GBFD-510104
GBFD-111005
GBFD-111202
GBFD-111801
GBFD-111803
None
GBFD-510002
GBFD-111203
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-118622
GBFD-118611
GBFD-113701
GBFD-114101
GBFD-117301
GBFD-118201
None
GBFD-111207
GBFD-114701
GBFD-111203
MRFD-210301
MRFD-211501
GBFD-111202
GBFD-111203
GBFD-111005
GBFD-111005
GBFD-119501
GBFD-119501
GBFD-114701
GBFD-111202
GBFD-111207
GBFD-111202
GBFD-111207
GBFD-111202
GBFD-111603
GBFD-111202
None
None
GBFD-111610
GBFD-111610
GBFD-111610
GBFD-111610
GBFD-111610
GBFD-111202
GBFD-111202
GBFD-118201
GBFD-118201
GBFD-118201
GBFD-118201
GBFD-118201
GBFD-118201
GBFD-118201
GBFD-111003
GBFD-110301
GBFD-118701
GBFD-118701
GBFD-118701
GBFD-118701
GBFD-118701
GBFD-118701
GBFD-118701
GBFD-118701
GBFD-118605
GBFD-118605
None
GBFD-119110
MRFD-210301
GBFD-111203
GBFD-110101
GBFD-114101
GBFD-510701
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118602
GBFD-111005
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118601
GBFD-118602
GBFD-118604
GBFD-118610
GBFD-118604
GBFD-118610
GBFD-118603
GBFD-118603
GBFD-111203
MRFD-210305
GBFD-111202
GBFD-510301
GBFD-510302
None
MRFD-210304
MRFD-210304
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-510501
GBFD-510501
GBFD-119501
GBFD-111203
GBFD-119105
GBFD-110601
GBFD-510501
GBFD-119105
GBFD-119105
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-115501
GBFD-115501
GBFD-115501
GBFD-115502
GBFD-115502
GBFD-115502
GBFD-115507
GBFD-115507
GBFD-511103
GBFD-110703
GBFD-117601
GBFD-117601
GBFD-511103
GBFD-110703
GBFD-110703
GBFD-110703
GBFD-110703
GBFD-110703
GBFD-110703
GBFD-110601
GBFD-510501
GBFD-115501
GBFD-510501
GBFD-115502
GBFD-510501
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-117601
GBFD-110703
GBFD-110703
GBFD-115501
GBFD-115507
GBFD-115501
GBFD-115507
GBFD-115501
GBFD-115507
GBFD-115502
GBFD-115502
GBFD-115502
GBFD-115507
GBFD-115507
GBFD-113201
GBFD-119105
GBFD-111203
GBFD-110601
GBFD-510501
MRFD-210301
None
GBFD-510002
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210304
MRFD-210601
MRFD-210304
MRFD-210601
MRFD-210304
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-113602
GBFD-114101
GBFD-119106
GBFD-114201
GBFD-119106
GBFD-114101
GBFD-113101
GBFD-510803
GBFD-510803
GBFD-119203
GBFD-114101
GBFD-119106
GBFD-114201
GBFD-119106
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-510309
GBFD-118601
GBFD-110703
GBFD-117601
GBFD-118605
None
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110601
GBFD-510501
GBFD-110203
GBFD-119203
GBFD-119106
GBFD-118901
GBFD-119106
GBFD-118901
GBFD-119106
GBFD-119106
GBFD-118901
GBFD-119106
GBFD-118901
GBFD-119106
GBFD-116201
GBFD-111203
GBFD-114101
GBFD-111203
MRFD-210403
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-113201
GBFD-113201
GBFD-113201
GBFD-113201
GBFD-113201
GBFD-113201
GBFD-114301
GBFD-114302
GBFD-111202
GBFD-510301
GBFD-510302
GBFD-510301
GBFD-510302
GBFD-510301
GBFD-510302
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-111705
GBFD-118605
None
None
None
GBFD-118611
GBFD-118622
GBFD-118630
GBFD-118601
GBFD-118630
MRFD-210301
None
None
None
GBFD-118601
GBFD-118601
MRFD-210301
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-111202
MRFD-210304
MRFD-210304
MRFD-210304
GBFD-111202
GBFD-111202
GBFD-110501
GBFD-115501
GBFD-115502
None
GBFD-110202
GBFD-110521
GBFD-117002
None
GBFD-111202
MRFD-210304
GBFD-111203
MRFD-210305
GBFD-115402
GBFD-118201
GBFD-111202
GBFD-118609
GBFD-118601
GBFD-111203
MRFD-210305
GBFD-118602
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
GBFD-111202
MRFD-210301
GBFD-111202
MRFD-210301
None
GBFD-111202
GBFD-111203
GBFD-113728
GBFD-117801
GBFD-111701
GBFD-116101
MRFD-210301
Feature Name
Assignment and Immediate Assignment
Assignment and Immediate Assignment
Assignment and Immediate Assignment
Abis Bypass
GSM Flow Control
GSM Flow Control
GSM Flow Control
EGPRS
EGPRS
BTS Local Switch
Flex Abis
PDCH Dynamic Adjustment
Configuration Management
Soft-Synchronized Network
Voice Quality Index (Uplink VQI)
Access
Access
Access Control Class(ACC)
Access Control Class(ACC)
Concentric Cell
Access Control Class(ACC)
Adaptive Adjustment of Uplink and Downlink Channels
Access Control Class(ACC)
Access Control Class(ACC)
Access Control Class(ACC)
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
BSS Paging Coordination
Basic Cell Re-selection
System Information Sending
AMR FR
TFO
AMR HR
TFO
WB AMR
TFO
Call Control
Handover Re-establishment
Soft-Synchronized Network
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
HUAWEI I Handover
HUAWEI II Handover
O&M of BTS
GSM Flow Control
GSM Flow Control
O&M of BTS
A Interface Protocol Process
Soft-Synchronized Network
Dynamically Adjusting the Uplink MCS Coding
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Soft-Synchronized Network
Soft-Synchronized Network
Soft-Synchronized Network
Soft-Synchronized Network
Faulty Management
O&M of BTS
O&M of BTS
Acoustic Echo Cancellation(AEC)
Acoustic Echo Cancellation(AEC)
Acoustic Echo Cancellation(AEC)
Acoustic Echo Cancellation(AEC)
Acoustic Echo Cancellation(AEC)
Acoustic Echo Cancellation(AEC)
Acoustic Echo Cancellation(AEC)
Acoustic Echo Cancellation(AEC)
AMR Wireless Link Timer
AMR Wireless Link Timer
BSC/RNC Clock
BSC/RNC Clock
AMR Wireless Link Timer
AMR Wireless Link Timer
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
O&M of BTS
Faulty Management
TRX Cooperation
Faulty Management
Faulty Management
End-to-End MS Signaling Tracing
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
A over IP
Automatic Level Control (ALC)
Automatic Level Control (ALC)
Automatic Level Control (ALC)
Automatic Level Control (ALC)
Automatic Level Control (ALC)
Automatic Level Control (ALC)
Automatic Level Control (ALC)
Gb Over FR
Gb Over FR
IP QOS
GPRS
PDCH Dynamic Adjustment
Enhanced Channel Assignment Algorithm
EDA(Extended Dynamic Allocation)
Network-Controlled Cell Reselection (NC2)
Enhanced Channel Assignment Algorithm
A Interface Circuit Management
O&M of BSC
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Power Control
BSS-Based LCS (Cell ID + TA)
BSC/RNC Clock
BSS-Based LCS (Cell ID + TA)
BSC/RNC Clock
Faulty Management
Faulty Management
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
AMR Power Control
HUAWEI III Power Control Algorithm
AMR Coding Rate Threshold Adaptive Adjustment
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
Enhanced Power Control Algorithm
AMR HR
AMR HR
AMR Coding Rate Threshold Adaptive Adjustment
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
AMR Power Control
A Interface Circuit Management
A Interface Circuit Management
Automatic Noise Compensation (ANC)
Automatic Noise Compensation (ANC)
Automatic Noise Compensation (ANC)
Remote Electrical Tilt
Abis over IP
A over IP
None
Faulty Management
Automatic Noise Restraint (ANR)
Automatic Noise Restraint (ANR)
Automatic Noise Restraint (ANR)
Automatic Noise Restraint (ANR)
BSS-Based LCS (Cell ID + TA)
Soft-Synchronized Network
BTS GPS Synchronization
BTS/NodeB Clock
BTS GPS Synchronization
BTS/NodeB Clock
Abis IP over E1/T1
A IP over E1/T1
O&M of BTS
Remote Electrical Tilt
O&M of BTS
Multi-site Cell
O&M of BTS
A Interface Protocol Process
A over IP
Semi-Permanent Connection
PS Active Package Management
PS Active Package Management
PS Active Package Management
PS Active Package Management
PS Active Package Management
PS Active Package Management
PS Active Package Management
PS Active Package Management
Configuration Management
BSC/RNC Software Management
BSC/RNC Software Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
IP Fault Detection Based on BFD
Abis IP over E1/T1
A IP over E1/T1
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
Faulty Management
Faulty Management
Assignment and Immediate Assignment
Direct Retry
Concentric Cell
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
2G/3G Neighboring Cell Automatic Optimization
Assignment and Immediate Assignment
O&M of BSC
A Interface Circuit Management
GSM Flow Control
GSM Flow Control
O&M of BSC
A Interface Circuit Management
O&M of BSC
A Interface Circuit Management
Concentric Cell
Enhanced Dual-Band Network
Enhanced Dual-Band Network
Flex Ater
Flex Ater
Flex Ater
O&M of BSC
BSC Local Switch
O&M of BSC
Semi-Permanent Connection
Configuration Management
Configuration Management
O&M of BSC
Ater Compression Transmission
O&M of BTS
A Interface Protocol Process
IMSI Detach
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
None
None
Security Management
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
IP Fault Detection Based on BFD
Configuration Management
AMR FR
AMR HR
O&M of BTS
Abis over IP
O&M of BTS
Security Management
Security Management
None
A Interface Protocol Process
Faulty Management
Faulty Management
None
None
None
None
BSC/RNC Clock
BSC/RNC Clock
O&M of BSC
Security Management
Configuration Management
Radio Dedicated Channel Management
GPRS
None
IP Fault Detection Based on BFD
IP Fault Detection Based on BFD
Active Backup Power Control
Active Backup Power Control
Multi-band Sharing One BSC
Multi-band Sharing One BSC
Multi-band Sharing One BSC
HUAWEI I Handover
HUAWEI II Handover
O&M of BTS
Soft-Synchronized Network
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
BSC Node Redundancy
Processing of Measurement Report
Pre-processing of Measurement Report
O&M of BTS
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Frequency Band
Frequency Hopping (RF hopping, baseband hopping)
Gb Over FR
Gb Over FR
Gb over IP
Gb Over FR
O&M of BTS
O&M of BTS
O&M of BTS
QoS ARP&THP
QoS ARP&THP
QoS ARP&THP
A Interface Protocol Process
STP(Signaling Transport Point)
BSC Node Redundancy
EGPRS
GSM/TD-SCDMA Interoperability
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
IP Fault Detection Based on BFD
IP Fault Detection Based on BFD
Processing of Measurement Report
Pre-processing of Measurement Report
TRX Cooperation
Soft-Synchronized Network
QoS ARP&THP
QoS ARP&THP
QoS ARP&THP
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Gb Over FR
Gb Over FR
None
None
None
GSM Flow Control
Abis IP over E1/T1
A IP over E1/T1
Faulty Management
O&M of BTS
O&M of BTS
HUAWEI I Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI II Handover
Configuration Management
Configuration Management
Configuration Management
Configuration Management
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Configuration Management
Configuration Management
None
None
None
None
O&M of BTS
O&M of BTS
Fast Ring Network Switch
Simplified Cell Broadcast
Simplified Cell Broadcast
O&M of BSC
Security Management
Radio Common Channel Management
Location Updating
A over IP
TRX Power Amplifier Intelligent Shutdown
A Interface Circuit Management
TC Pool
Short Message Service Cell Broadcast (TS23)
Soft-Synchronized Network
Soft-Synchronized Network
Ater Compression Transmission
IP QOS
Configuration Management
Soft-Synchronized Network
Short Message Service Cell Broadcast (TS23)
Abis over IP
BSC Local Switch
Connection Inter BSC over IP
Enhanced Multi Level Precedence and Preemption(EMLPP)
Enhanced Multi Level Precedence and Preemption(EMLPP)
Semi-Permanent Connection
Short Message Service Cell Broadcast (TS23)
Enhanced Multi Level Precedence and Preemption(EMLPP)
Enhanced Multi Level Precedence and Preemption(EMLPP)
Enhanced Multi Level Precedence and Preemption(EMLPP)
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Semi-Permanent Connection
Semi-Permanent Connection
Semi-Permanent Connection
Soft-Synchronized Network
TC Pool
TC Pool
Semi-Permanent Connection
GPRS
Pre-processing of Measurement Report
Configuration Management
Paging
Radio Common Channel Management
Configuration Management
Configuration Management
BSC Local Switch
BTS Local Switch
BSC Local Switch
BTS Local Switch
BSS Paging Coordination
BSS Paging Coordination
BSC/RNC Clock
BSC/RNC Software Management
BSC/RNC Software Management
None
None
None
None
None
None
None
Remote Electrical Tilt
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Ater Interface 4:1 Multiplexing
TC Pool
Ater Interface 4:1 Multiplexing
O&M of BTS
O&M of BTS
Abis over IP
Abis over IP
O&M of BTS
Abis over IP
IP QOS
O&M of BTS
O&M of BTS
Abis Transmission Optimization
O&M of BTS
Soft-Synchronized Network
Remote Electrical Tilt
Security Management
Abis over IP
BTS Local Switch
Abis over IP
Pre-processing of Measurement Report
O&M of BTS
Abis Transmission Optimization
O&M of BTS
Abis over IP
Active Backup Power Control
Enhanced Power Control Algorithm
Network Support SAIC
O&M of BTS
Abis Transmission Optimization
O&M of BTS
Compact BTS Automatic Configuration and Planning
O&M of BTS
IP Fault Detection Based on BFD
BTS Test Function
O&M of BTS
Fast Ring Network Switch
A over IP
Gb Interface Function
Gb Interface Function
Gb Interface Function
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
Processing of Measurement Report
Pre-processing of Measurement Report
Configuration Management
GPRS
GPRS
O&M of BTS
O&M of BTS
Configuration Management
Call Reestablishment
O&M of BTS
Frequency Hopping (RF hopping, baseband hopping)
System Information Sending
Compact BTS Automatic Capacity Planning
O&M of BTS
IP QOS
IP QOS
None
Basic Cell Selection
Basic Cell Re-selection
Short Message Service Cell Broadcast (TS23)
Short Message Service Cell Broadcast (TS23)
Short Message Service Cell Broadcast (TS23)
Short Message Service Cell Broadcast (TS23)
Short Message Service Cell Broadcast (TS23)
Basic Cell Selection
Location Updating
IP QOS
Short Message Service Cell Broadcast (TS23)
Enhanced Measurement Report(EMR)
Enhanced Measurement Report(EMR)
Configuration Management
Security Management
Radio Common Channel Management
Radio Common Channel Management
Gb over IP
Ethernet OAM
Direct Retry
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Power Control
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
System Information Sending
GPRS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Configuration Management
Configuration Management
MBSC Load Balancing
Configuration Management
Configuration Management
O&M of BTS
2G/3G Neighboring Cell Automatic Optimization
Configuration Management
Configuration Management
Remote Electrical Tilt
Enhanced Dual-Band Network
HUAWEI I Handover
HUAWEI II Handover
Configuration Management
A Interface Protocol Process
SDCCH Dynamic Adjustment
Configuration Management
MBSC Load Balancing
O&M of BTS
Configuration Management
RAN Sharing
Processing of Measurement Report
Pre-processing of Measurement Report
Processing of Measurement Report
Pre-processing of Measurement Report
Radio Common Channel Management
O&M of BTS
O&M of BTS
Network-Controlled Cell Reselection (NC2)
Network-Controlled Cell Reselection (NC2)
Uplink EGPRS2-A
Downlink EGPRS2-A
Fast 3G Reselection at 2G CS Call Release
Faulty Management
Faulty Management
O&M of BTS
O&M of BTS
O&M of BTS
Processing of Measurement Report
Pre-processing of Measurement Report
Processing of Measurement Report
Pre-processing of Measurement Report
GSM Flow Control
Security Management
O&M of BTS
IP QOS
Compact BTS Automatic Configuration and Planning
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BSC
Security Management
O&M of BSC
Security Management
O&M of BSC
Security Management
O&M of BSC
O&M of BSC
PICO Automatic Configuration and Planning
O&M of BSC
Security Management
GPRS
O&M of BSC
O&M of BSC
O&M of BSC
Chain Cell Handover
O&M of BTS
Enhanced Channel Assignment Algorithm
None
O&M of BSC
O&M of BSC
Simplified Cell Broadcast
Enhanced Channel Assignment Algorithm
A Interface Protocol Process
None
IP QOS
Tree Topology
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
IP Fault Detection Based on BFD
IP Fault Detection Based on BFD
O&M of BTS
O&M of BTS
A over IP
A over IP
A over IP
IP Fault Detection Based on BFD
BTS Test Function
Configuration Management
O&M of BSC
Configuration Management
BTS Test Function
Configuration Management
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
Enhanced Channel Assignment Algorithm
None
GSM Flow Control
GSM Flow Control
GSM Flow Control
Configuration Management
Configuration Management
Configuration Management
A Interface Circuit Management
O&M of BSC
Voice Fault Diagnosis
Voice Fault Diagnosis
Voice Fault Diagnosis
Voice Fault Diagnosis
Voice Fault Diagnosis
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
IP QOS
Enhanced Channel Assignment Algorithm
O&M of BTS
O&M of BTS
Class11 DTM
Call Control
Abis IP over E1/T1
A IP over E1/T1
O&M of BTS
O&M of BTS
BSC/RNC Clock
BTS/NodeB Clock
O&M of BTS
Faulty Management
O&M of BTS
O&M of BSC
Security Management
O&M of BSC
Security Management
O&M of BSC
Configuration Management
O&M of BTS
IP Fault Detection Based on BFD
O&M of BTS
O&M of BTS
O&M of BTS
BSC Node Redundancy
MSC Pool
SGSN Pool
MSC Pool
License Management
BSC Node Redundancy
Faulty Management
O&M of BTS
O&M of BTS
O&M of BSC
Security Management
Faulty Management
Faulty Management
HUAWEI I Handover
HUAWEI II Handover
Simplified Cell Broadcast
O&M of BTS
Soft-Synchronized Network
Active Power Control
Radio Common Channel Management
Location Updating
Security Management
O&M of BTS
HUAWEI I Handover
HUAWEI II Handover
O&M of BTS
2G/3G Co-Transmission Resources Management on MBSC
None
None
None
None
2G/3G Co-Transmission Resources Management on MBSC
2G/3G Co-Transmission Resources Management on MBSC
None
None
None
None
2G/3G Co-Transmission Resources Management on MBSC
HUAWEI I Handover
HUAWEI II Handover
Tree Topology
Configuration Management
O&M of BSC
Security Management
MBSC Load Balancing
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
2G/3G Co-Transmission Resources Management on MBSC
2G/3G Co-Transmission Resources Management on MBSC
BTS Test Function
TRX Power Amplifier Intelligent Shutdown
Configuration Management
O&M of BTS
Basic Cell Re-selection
Location Updating
Security Management
Security Management
Public Voice Group Call Service
Public Voice Broadcast Service
Public Voice Group Call Service
Public Voice Broadcast Service
Basic Cell Re-selection
O&M of BSC
A over IP
A IP over E1/T1
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
IP QOS
IP QOS
IP QOS
IP QOS
GSM Flow Control
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
GSM Flow Control
O&M of BSC
IP QOS
O&M of BSC
IP QOS
IP QOS
IP QOS
GSM Flow Control
None
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
GSM Flow Control
GSM Flow Control
Soft-Synchronized Network
GPRS
O&M of BTS
Remote Electrical Tilt
Remote Electrical Tilt
Remote Electrical Tilt
Remote Electrical Tilt
IP QOS
O&M of BTS
O&M of BTS
Configuration Management
A Interface Protocol Process
O&M of BTS
None
BSC/RNC Software Management
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
G3 Fax (TS61, TS62)
14.4kbit/s Circuit Switched Data
O&M of BSC
Security Management
O&M of BSC
TRX Power Amplifier Intelligent Shutdown
O&M of BTS
O&M of BTS
Co-BCCH Cell
Enhanced Dual-Band Network
Enhanced Dual-Band Network
Enhanced Dual-Band Network
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Faulty Management
Faulty Management
O&M of BTS
PDCH Dynamic Adjustment
Call Control
A over IP
A IP over E1/T1
O&M of BSC
Security Management
O&M of BTS
None
None
None
None
Compact BTS Automatic Configuration and Planning
O&M of BTS
MBSC Load Balancing
MBSC Load Balancing
MBSC Load Balancing
Configuration Management
O&M of BSC
IP Fault Detection Based on BFD
O&M of BTS
Remote Electrical Tilt
Remote Electrical Tilt
None
None
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
O&M of BTS
O&M of BTS
MSC Pool
O&M of BSC
Security Management
BSC/RNC Clock
Abis IP over E1/T1
A IP over E1/T1
None
O&M of BTS
SDCCH Handover
Enhanced Channel Assignment Algorithm
O&M of BSC
O&M of BSC
O&M of BSC
License Management
O&M of BTS
Direct Retry
Direct Retry
HUAWEI I Handover
HUAWEI I Handover
HUAWEI II Handover
GSM/WCDMA Interoperability
Downlink EGPRS2-A
Downlink EGPRS2-A
EGPRS
Transmit Diversity
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
Gb Over FR
Adaptive Adjustment of Uplink and Downlink Channels
Dual Carriers in Downlink
HUAWEI I Handover
HUAWEI II Handover
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
GPRS
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
AMR FR
AMR FR
AMR FR
AMR HR
AMR HR
AMR HR
WB AMR
WB AMR
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
GSM and UMTS Load Balancing Based on Iur-g
Enhanced Power Control Algorithm
AMR Coding Rate Threshold Adaptive Adjustment
AMR Coding Rate Threshold Adaptive Adjustment
AMR Coding Rate Threshold Adaptive Adjustment
AMR Coding Rate Threshold Adaptive Adjustment
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
GSM and UMTS Load Balancing Based on Iur-g
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
HUAWEI I Handover
HUAWEI II Handover
AMR FR
HUAWEI II Handover
AMR HR
HUAWEI II Handover
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
Extended Uplink TBF
Public Voice Group Call Service
Public Voice Broadcast Service
Public Voice Group Call Service
Public Voice Broadcast Service
AMR FR
AMR FR
AMR FR
AMR HR
AMR HR
AMR HR
WB AMR
WB AMR
O&M of BTS
O&M of BTS
Clock over IP support 1588V2
Coding Scheme
EGPRS
Coding Scheme
Downlink EGPRS2-A
Downlink EGPRS2-A
GPRS
Coding Scheme
EGPRS
Coding Scheme
Enhanced Power Control Algorithm
HUAWEI III Power Control Algorithm
Point To Point Short Message Service (TS21, TS22)
GPRS
Coding Scheme
CS-3/CS-4
Coding Scheme
CS-3/CS-4
Coding Scheme
Coding Scheme
CS-3/CS-4
Coding Scheme
CS-3/CS-4
Coding Scheme
Faulty Management
Active Power Control
A Interface Protocol Process
STP(Signaling Transport Point)
A Interface Protocol Process
A Interface Circuit Management
A Interface Circuit Management
MSC Pool
A Interface Protocol Process
STP(Signaling Transport Point)
A Interface Protocol Process
A over IP
MBSC Load Balancing
HUAWEI I Handover
HUAWEI II Handover
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
None
2G/3G Co-Transmission Resources Management on MBSC
2G/3G Co-Transmission Resources Management on MBSC
2G/3G Co-Transmission Resources Management on MBSC
2G/3G Co-Transmission Resources Management on MBSC
2G/3G Co-Transmission Resources Management on MBSC
Active Backup Power Control
Active Backup Power Control
Active Backup Power Control
Simplified Cell Broadcast
Discontinuous Reception (DRX)
O&M of BTS
None
Abis IP over E1/T1
A IP over E1/T1
A over IP
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
IP QOS
GPRS
Configuration Management
Configuration Management
Faulty Management
Configuration Management
GPRS
GPRS
Support of Daylight Saving Time
Configuration Management
O&M of BTS
None
IP Fault Detection Based on BFD
Abis over IP
None
Abis over IP
None
None
Direct Retry
Public Voice Group Call Service
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
A5/1 Encryption Flow Optimization
Abis over IP
BTS Test Function
BTS Test Function
BTS Test Function
BTS Test Function
GPRS
PDCH Dynamic Adjustment
Soft-Synchronized Network
O&M of BTS
O&M of BSC
O&M of BTS
PDCH Dynamic Adjustment
GPRS
PDCH Dynamic Adjustment
GPRS
PDCH Dynamic Adjustment
TRX Power Amplifier Intelligent Shutdown
Dynamic Transmit Diversity
O&M of BTS
O&M of BTS
Abis Transmission Optimization
BTS Test Function
None
BTS/NodeB Clock
IP-Based 2G/3G Co-Transmission on Base Station Side
BTS/NodeB Clock
IP QOS
GSM/WCDMA Interoperability
GSM/WCDMA Interoperability
System Information Sending
Faulty Management
O&M of BSC
Faulty Management
Faulty Management
O&M of BTS
Support of Daylight Saving Time
Configuration Management
Enhanced Dual-Band Network
Enhanced Dual-Band Network
Enhanced Dual-Band Network
EGPRS
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
O&M of BTS
11-Bit EGPRS Access
Uplink EGPRS2-A
Downlink EGPRS2-A
Network-Controlled Cell Reselection (NC2)
Network-Controlled Cell Reselection (NC2)
Support of Daylight Saving Time
Configuration Management
Emergency Call Service (TS12)
Guaranteed Emergency Call
A Interface Protocol Process
None
Abis IP over E1/T1
A IP over E1/T1
Enhanced Multi Level Precedence and Preemption(EMLPP)
Group Call EMLPP
Enhanced Multi Level Precedence and Preemption(EMLPP)
Abis IP over E1/T1
A IP over E1/T1
IP QOS
O&M of BTS
Support of Daylight Saving Time
Configuration Management
O&M of BTS
Group Call Reliability Enhancing
O&M of BTS
A5/1 and A5/2 Ciphering Algorithm
A5/3 Ciphering Algorithm
O&M of BSC
O&M of BSC
End-to-End MS Signaling Tracing
Faulty Management
A Interface Circuit Management
O&M of BSC
TRX Power Amplifier Intelligent Shutdown
O&M of BTS
TRX Power Amplifier Intelligent Shutdown
O&M of BTS
TRX Power Amplifier Intelligent Shutdown
Ater Interface 4:1 Multiplexing
A Interface Circuit Management
O&M of BTS
O&M of BSC
O&M of BSC
Concentric Cell
2G/3G Co-Transmission Resources Management on MBSC
Concentric Cell
Concentric Cell
Concentric Cell
Concentric Cell
IP QOS
IP QOS
Concentric Cell
Dynamic Adjustment Between FR and HR
A over IP
A IP over E1/T1
A over IP
Concentric Cell
Enhancement Packet Loss Concealment(EPLC)
O&M of BSC
Security Management
Emergency Call Service (TS12)
Ethernet OAM
Ethernet OAM
None
None
IP QOS
O&M of BTS
Faulty Management
Assignment and Immediate Assignment
Simple Mode LCS(Cell ID + TA)
Fast Ring Network Switch
Support of Daylight Saving Time
Configuration Management
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
Security Management
Faulty Management
Faulty Management
Simplified Cell Broadcast
O&M of BSC
Security Management
O&M of BTS
O&M of BSC
Security Management
O&M of BSC
Security Management
Support of Daylight Saving Time
Configuration Management
Support of Daylight Saving Time
Configuration Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
GPRS
O&M of BSC
Active Power Control
Active Power Control
Configuration Management
O&M of BTS
Configuration Management
O&M of BTS
Configuration Management
Configuration Management
Extended Cell
O&M of BTS
Processing of Measurement Report
Pre-processing of Measurement Report
Processing of Measurement Report
Pre-processing of Measurement Report
Processing of Measurement Report
Pre-processing of Measurement Report
Extended Cell
Extended Uplink TBF
Public Voice Group Call Service
Public Voice Broadcast Service
Group Call EMLPP
Group Call EMLPP
O&M of BTS
Enhanced Channel Assignment Algorithm
HUAWEI I Handover
HUAWEI II Handover
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Assignment and Immediate Assignment
Fast Ring Network Switch
O&M of BSC
None
Abis over IP
GSM Flow Control
None
None
Abis IP over E1/T1
A IP over E1/T1
None
None
2G/3G Co-Transmission Resources Management on MBSC
None
Compact BTS Automatic Configuration and Planning
O&M of BTS
GSM Flow Control
Link aggregation
O&M of BTS
GSM Flow Control
O&M of BTS
GSM/WCDMA Interoperability
Configuration Management
GSM/WCDMA Interoperability
GSM/WCDMA Interoperability
GSM/WCDMA Interoperability
GSM/WCDMA Interoperability
GSM/WCDMA Interoperability
GSM/WCDMA Interoperability
GSM/WCDMA Interoperability
GSM/WCDMA Interoperability
GSM/WCDMA Interoperability
GSM/WCDMA Interoperability
Processing of Measurement Report
GSM/WCDMA Interoperability
GSM/WCDMA Interoperability
GSM/WCDMA Interoperability
GSM Flow Control
Voice Quality Index (Uplink VQI)
Voice Quality Index (Uplink VQI)
Voice Quality Index (Uplink VQI)
Voice Quality Index (Uplink VQI)
Voice Quality Index (Uplink VQI)
Voice Quality Index (Uplink VQI)
Voice Quality Index (Uplink VQI)
Voice Quality Index (Uplink VQI)
Frequency Hopping (RF hopping, baseband hopping)
O&M of BSC
Security Management
O&M of BSC
BSC/RNC Software Management
O&M of BSC
Security Management
Configuration Management
O&M of BSC
Faulty Management
Network-Controlled Cell Reselection (NC2)
O&M of BSC
Security Management
HUAWEI III Power Control Algorithm
O&M of BTS
Flex Abis
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Flex Abis
Flex MAIO
A5/1 Encryption Flow Optimization
Soft-Synchronized Network
Adaptive Adjustment of Uplink and Downlink Channels
Adaptive Adjustment of Uplink and Downlink Channels
None
None
None
Abis IP over E1/T1
A IP over E1/T1
None
IP QOS
2G/3G Co-Transmission Resources Management on MBSC
HUAWEI I Handover
HUAWEI I Handover
HUAWEI I Handover
HUAWEI I Handover
HUAWEI I Handover
HUAWEI I Handover
HUAWEI I Handover
HUAWEI I Handover
HUAWEI I Handover
GPRS
Radio Common Channel Management
System Information Sending
O&M of BTS
Inventory Management
O&M of BSC
BSC/RNC Software Management
O&M of BSC
Configuration Management
License Management
O&M of BTS
O&M of BTS
PDCH Dynamic Adjustment
EGPRS
A Interface Protocol Process
Automatic Level Control (ALC)
GPRS
Call Control
Enhanced Full Rate
HUAWEI I Handover
HUAWEI II Handover
O&M of BTS
O&M of BTS
None
Compact BTS Automatic Capacity Planning
PICO Automatic Configuration and Planning
Compact BTS Automatic Configuration and Planning
Abis MUX
UDP MUX for A Transmission
Soft-Synchronized Network
Configuration Management
Discontinuous Transmission (DTX) Downlink
AMR FR
O&M of BSC
Security Management
O&M of BSC
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
Frequency Band
AFC(Automatic Frequency Correction)
AFC(Automatic Frequency Correction)
Configuration Management
Enhanced Channel Assignment Algorithm
Cell Frequency Scan
Configuration Management
2G/3G Neighboring Cell Automatic Optimization
Cell Frequency Scan
HUAWEI I Handover
HUAWEI II Handover
Discontinuous Transmission (DTX) Uplink
AMR FR
Compact BTS Automatic Configuration and Planning
O&M of BTS
Compact BTS Automatic Configuration and Planning
O&M of BTS
O&M of BSC
Security Management
IP QOS
IP QOS
None
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
IP QOS
GSM and UMTS Load Balancing Based on Iur-g
GSM and UMTS Load Balancing Based on Iur-g
A over IP
Power Control
Soft-Synchronized Network
Soft-Synchronized Network
Soft-Synchronized Network
Soft-Synchronized Network
Streaming QoS(GBR)
Public Voice Group Call Service
Public Voice Broadcast Service
BSC/RNC Clock
Public Voice Group Call Service
Public Voice Broadcast Service
Group Call EMLPP
None
GPRS
System Information Sending
GPRS
GPRS
GPRS
EGPRS
GPRS
GPRS
Network-Controlled Cell Reselection (NC2)
GPRS
BTS GPS Synchronization
BTS/NodeB Clock
BSC/RNC Clock
Resource Reservation
Group Call Reliability Enhancing
Group Call Reliability Enhancing
BSC Node Redundancy
BSC Node Redundancy
Flex Abis
IP QOS
IP QOS
Simplified Cell Broadcast
IP QOS
IP QOS
Multi-band Sharing One BSC
GSM/TD-SCDMA Interoperability
O&M of BTS
Abis over IP
Abis over IP
Half Rate Speech
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
A over IP
O&M of BTS
HUAWEI II Handover
HUAWEI II Handover
O&M of BTS
O&M of BTS
Frequency Band
Enhanced Multi Level Precedence and Preemption(EMLPP)
Enhanced Multi Level Precedence and Preemption(EMLPP)
Enhanced Multi Level Precedence and Preemption(EMLPP)
O&M of BTS
Enhanced Channel Assignment Algorithm
Security Management
HMC DTM
Concentric Cell
RAN Sharing
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
O&M of BSC
O&M of BSC
HUAWEI I Handover
Chain Cell Handover
Chain Cell Handover
Chain Cell Handover
Fast Move Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
Fast Move Handover
O&M of BSC
HUAWEI I Handover
HUAWEI II Handover
Concentric Cell
HUAWEI I Handover
HUAWEI II Handover
Enhanced Dual-Band Network
Frequency Hopping (RF hopping, baseband hopping)
IBCA (Interference Based Channel Allocation)
Frequency Hopping (RF hopping, baseband hopping)
BTS power lift for handover
HUAWEI I Handover
HUAWEI II Handover
Frequency Hopping (RF hopping, baseband hopping)
Antenna Frequency Hopping
Antenna Frequency Hopping
Frequency Hopping (RF hopping, baseband hopping)
HUAWEI I Handover
HUAWEI II Handover
Soft-Synchronized Network
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
A Interface Protocol Process
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
Fast Move Handover
BSC Node Redundancy
BSC Node Redundancy
HUAWEI I Handover
HUAWEI II Handover
Fast Move Handover
Antenna Frequency Hopping
Antenna Frequency Hopping
O&M of BTS
Resource Reservation
O&M of BTS
BTS Power Management
O&M of BTS
BTS Power Management
Half Rate Speech
System Information Sending
Discontinuous Transmission (DTX) Downlink
Half Rate Speech
Concentric Cell
Discontinuous Transmission (DTX) Uplink
Half Rate Speech
Frequency Hopping (RF hopping, baseband hopping)
O&M of BTS
Flex MAIO
O&M of BTS
IP Fault Detection Based on BFD
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
O&M of BTS
A Interface Protocol Process
BTS Test Function
O&M of BTS
O&M of BTS
A Interface Protocol Process
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
Intelligent Combiner Bypass
O&M of BTS
IP QOS
Gb over IP
Gb over IP
Gb over IP
O&M of BSC
O&M of BSC
O&M of BTS
A over IP
None
SDCCH Dynamic Adjustment
O&M of BTS
None
Configuration Management
Configuration Management
MBSC Load Balancing
Configuration Management
O&M of BTS
O&M of BTS
Semi-Permanent Connection
Configuration Management
O&M of BSC
Short Message Service Cell Broadcast (TS23)
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Fast Move Handover
O&M of BSC
A Interface Protocol Process
Assignment and Immediate Assignment
Packet Assignment Taken Over by the BTS
Assignment and Immediate Assignment
Assignment and Immediate Assignment
Assignment and Immediate Assignment
Assignment and Immediate Assignment
Concentric Cell
Concentric Cell
Soft-Synchronized Network
Assignment and Immediate Assignment
O&M of BSC
GPRS
HUAWEI I Handover
HUAWEI II Handover
Soft-Synchronized Network
Soft-Synchronized Network
BSS-Based LCS (Cell ID + TA)
O&M of BTS
O&M of BTS
AMR FR/HR Dynamic Adjustment
AMR FR/HR Dynamic Adjustment
MBSC Load Balancing
Faulty Management
AMR FR/HR Dynamic Adjustment
AMR FR/HR Dynamic Adjustment
Enhanced Channel Assignment Algorithm
AMR FR
AMR HR
WB AMR
Semi-Permanent Connection
Enhanced Dual-Band Network
Enhanced Dual-Band Network
Configuration Management
Configuration Management
Enhanced Dual-Band Network
Enhanced Dual-Band Network
Enhanced Dual-Band Network
Enhanced Dual-Band Network
Semi-Permanent Connection
O&M of BTS
O&M of BSC
BSS-Based LCS (Cell ID + TA)
SDCCH Handover
Semi-Permanent Connection
O&M of BTS
Semi-Permanent Connection
O&M of BTS
Simplified Cell Broadcast
HUAWEI I Handover
HUAWEI II Handover
Cell Frequency Scan
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
Enhanced Channel Assignment Algorithm
TRX Management
Enhanced Channel Assignment Algorithm
TRX Management
Enhanced Channel Assignment Algorithm
TRX Management
Enhanced Channel Assignment Algorithm
TRX Management
Enhanced Channel Assignment Algorithm
TRX Management
Enhanced Channel Assignment Algorithm
TRX Management
Enhanced Channel Assignment Algorithm
Soft-Synchronized Network
Enhanced Channel Assignment Algorithm
GSM and UMTS Traffic Steering Based on Iur-g
GSM and UMTS Load Balancing Based on Iur-g
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
MBSC Handover based on Load Enhancement
GSM and UMTS Load Balancing Based on Iur-g
GSM and UMTS Load Balancing Based on Iur-g
GSM and UMTS Load Balancing Based on Iur-g
GSM and UMTS Load Balancing Based on Iur-g
GSM and UMTS Load Balancing Based on Iur-g
GSM and UMTS Load Balancing Based on Iur-g
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
GSM and UMTS Load Balancing Based on Iur-g
O&M of BSC
Security Management
None
Processing of Measurement Report
Pre-processing of Measurement Report
Enhanced Dual-Band Network
HUAWEI I Handover
HUAWEI I Handover
HUAWEI II Handover
AMR FR/HR Dynamic Adjustment
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
MBSC Load Balancing
GSM and UMTS Load Balancing Based on Iur-g
GSM and UMTS Load Balancing Based on Iur-g
GSM and UMTS Load Balancing Based on Iur-g
Semi-Permanent Connection
O&M of BSC
O&M of BSC
O&M of BSC
Enhanced Measurement Report(EMR)
Configuration Management
O&M of BSC
License Management
Gb over IP
Gb over IP
Abis over IP
O&M of BTS
IP QOS
Abis IP over E1/T1
A IP over E1/T1
IP-Based 2G/3G Co-Transmission on MBSC Side
None
None
None
Gb over IP
Gb over IP
Clock over IP
Gb over IP
Clock over IP
Gb over IP
Gb over IP
Ethernet OAM
Ethernet OAM
Abis IP over E1/T1
A IP over E1/T1
Link aggregation
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
None
Abis over IP
Abis over IP
O&M of BTS
Soft-Synchronized Network
Chain Cell Handover
Clock over IP
Clock over IP
Ring Topology
O&M of BTS
EGPRS
IP QOS
GPRS
Configuration Management
TC Pool
Multi-site Cell
Network-Controlled Cell Reselection (NC2)
Gb over IP
None
Soft-Synchronized Network
O&M of BTS
Abis Transmission Backup
BTS Local Switch
TC Pool
Configuration Management
Configuration Management
O&M of BTS
O&M of BTS
Intelligent Shutdown of TRX Due to PSU Failure
Configuration Management
Configuration Management
Configuration Management
Configuration Management
IP QOS
IP QOS
Concentric Cell
PDCH Dynamic Adjustment
Concentric Cell
Concentric Cell
Concentric Cell
Concentric Cell
Enhanced Dual-Band Network
Ethernet OAM
Abis MUX
UDP MUX for A Transmission
None
None
None
None
None
None
None
None
None
None
None
None
None
None
Abis Transmission Optimization
Multi-Carrier Intelligent Voltage Regulation
Abis over IP
None
HUAWEI I Handover
HUAWEI II Handover
None
Configuration Management
Compact BTS Automatic Capacity Planning
Board Switchover
BSS-Based LCS (Cell ID + TA)
BSS-Based LCS (Cell ID + TA)
BSS-Based LCS (Cell ID + TA)
BSS-Based LCS (Cell ID + TA)
BSS-Based LCS (Cell ID + TA)
BSS-Based LCS (Cell ID + TA)
BSC/RNC Clock
BSC/RNC Clock
Link aggregation
None
IP QOS
IP QOS
IP QOS
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
None
None
Abis over IP
Flex Abis
Abis over IP
Flex Abis
Abis over IP
Flex Abis
A over IP
A IP over E1/T1
O&M of BSC
Security Management
O&M of BSC
None
IP QOS
Processing of Measurement Report
Pre-processing of Measurement Report
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
Configuration Management
Configuration Management
Abis IP over E1/T1
A IP over E1/T1
Configuration Management
O&M of BSC
O&M of BTS
Faulty Management
Faulty Management
O&M of BSC
None
A Interface Protocol Process
Faulty Management
Configuration Management
Abis IP over E1/T1
A IP over E1/T1
O&M of BTS
O&M of BTS
None
Semi-Permanent Connection
A over IP
A IP over E1/T1
A Interface Protocol Process
A over IP
HUAWEI I Handover
HUAWEI II Handover
MSC Pool
Network-Controlled Cell Reselection (NC2)
O&M of BTS
HUAWEI I Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI I Handover
HUAWEI II Handover
O&M of BTS
Network-Controlled Cell Reselection (NC2)
Network-Controlled Cell Reselection (NC2)
Network-Controlled Cell Reselection (NC2)
GSM/WCDMA Interoperability
Network-Controlled Cell Reselection (NC2)
Enhanced Channel Assignment Algorithm
HUAWEI I Handover
None
BSC Node Redundancy
None
O&M of BTS
Abis IP over E1/T1
Abis IP over E1/T1
Gb over IP
Gb over IP
Multi-site Cell
Multi-site Cell
Faulty Management
A over IP
A IP over E1/T1
A over IP
A IP over E1/T1
O&M of BSC
Security Management
A over IP
A IP over E1/T1
Configuration Management
O&M of BTS
GSM Flow Control
GSM Flow Control
None
None
None
GSM Flow Control
GSM Flow Control
GSM Flow Control
O&M of BSC
O&M of BTS
BSS-Based LCS (Cell ID + TA)
BSS-Based LCS (Cell ID + TA)
BSS-Based LCS (Cell ID + TA)
BSS-Based LCS (Cell ID + TA)
BSS-Based LCS (Cell ID + TA)
BSS-Based LCS (Cell ID + TA)
BSC/RNC Clock
BSC/RNC Clock
Configuration Management
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
O&M of BSC
IBCA (Interference Based Channel Allocation)
O&M of BSC
O&M of BSC
None
None
O&M of BSC
None
Flex Abis
Flex Abis
O&M of BTS
Concentric Cell
O&M of BTS
O&M of BTS
O&M of BTS
IP QOS
None
None
IP QOS
None
EGPRS
O&M of BTS
O&M of BTS
Abis over IP
Flex Abis
O&M of BSC
Security Management
Configuration Management
Configuration Management
BSC/RNC Software Management
O&M of BSC
Security Management
O&M of BSC
Security Management
O&M of BTS
O&M of BTS
AMR Coding Rate Threshold Adaptive Adjustment
AMR Coding Rate Threshold Adaptive Adjustment
AMR Coding Rate Threshold Adaptive Adjustment
AMR Coding Rate Threshold Adaptive Adjustment
Voice Fault Diagnosis
O&M of BTS
O&M of BTS
O&M of BTS
BTS Power Management
A over IP
Configuration Management
Ethernet OAM
Ethernet OAM
Frequency Hopping (RF hopping, baseband hopping)
None
Enhanced BCCH Power Consumption Optimization
Enhanced BCCH Power Consumption Optimization
Enhanced BCCH Power Consumption Optimization
Enhanced BCCH Power Consumption Optimization
Enhanced BCCH Power Consumption Optimization
Ethernet OAM
Abis over IP
Multi-site Cell
Tree Topology
O&M of BTS
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
IBCA (Interference Based Channel Allocation)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
O&M of BTS
Ethernet OAM
Configuration Management
None
Abis IP over E1/T1
A IP over E1/T1
Ethernet OAM
None
None
Short Message Service Cell Broadcast (TS23)
Abis over IP
Abis IP over E1/T1
Abis IP over E1/T1
Clock over IP
Clock over IP
Enhanced Power Control Algorithm
A over IP
IP Fault Detection Based on BFD
Link aggregation
HUAWEI I Handover
HUAWEI II Handover
GPRS
GPRS
Active Backup Power Control
Compact BTS Automatic Configuration and Planning
PICO Automatic Configuration and Planning
Compact BTS Automatic Capacity Planning
IP QOS
O&M of BTS
Abis MUX
UDP MUX for A Transmission
Abis IP over E1/T1
A IP over E1/T1
Security Management
Faulty Management
O&M of BTS
A over IP
GPRS
PDCH Dynamic Adjustment
GPRS
PDCH Dynamic Adjustment
GPRS
Security Management
O&M of BTS
O&M of BTS
HUAWEI I Handover
HUAWEI II Handover
Access
Access
Access
Access
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
Adjustment of Adaptive Timing Advance
Extended Cell
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
BSC/RNC Clock
Flex Abis
None
Enhanced Power Control Algorithm
Security Management
None
IP Fault Detection Based on BFD
Multi-band Sharing One BSC
System Information Sending
Enhanced Measurement Report(EMR)
Enhanced Measurement Report(EMR)
Soft-Synchronized Network
Soft-Synchronized Network
Configuration Management
Compact BTS Automatic Capacity Planning
None
Abis IP over E1/T1
Configuration Management
O&M of BTS
O&M of BTS
Enhanced Channel Assignment Algorithm
O&M of BTS
None
Ethernet OAM
Configuration Management
Ethernet OAM
Ethernet OAM
Configuration Management
Packet System Information
GSM and UMTS Load Balancing Based on Iur-g
Enhanced Measurement Report(EMR)
Processing of Measurement Report
Ethernet OAM
Ethernet OAM
Configuration Management
Ethernet OAM
Ethernet OAM
Abis IP over E1/T1
Network-Controlled Cell Reselection (NC2)
Abis IP over E1/T1
A IP over E1/T1
GSM/WCDMA Interoperability
HUAWEI I Handover
HUAWEI II Handover
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Direct Retry
SDCCH Dynamic Adjustment
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
None
IP Fault Detection Based on BFD
IP Fault Detection Based on BFD
IP Fault Detection Based on BFD
IP Fault Detection Based on BFD
None
None
Configuration Management
Compact BTS Automatic Capacity Planning
GSM Flow Control
BSC/RNC Clock
A over IP
A IP over E1/T1
Configuration Management
Configuration Management
None
None
Board Switchover
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
O&M of BTS
Reporting the Temperature List of the BTS Equipment Room
O&M of BTS
Reporting the Temperature List of the BTS Equipment Room
O&M of BTS
Fast Move Handover
Abis IP over E1/T1
Abis IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
None
Abis IP over E1/T1
LAPD Multiplexing at Abis Interface
O&M of BTS
Abis IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Configuration Management
Configuration Management
Enhanced Power Control Algorithm
HUAWEI I Handover
HUAWEI II Handover
HUAWEI III Power Control Algorithm
Pre-processing of Measurement Report
O&M of BTS
O&M of BTS
O&M of BSC
O&M of BSC
Abis over IP
Soft-Synchronized Network
Call Control
MSC Pool
MSC Pool
MSC Pool
MSC Pool
MSC Pool
A Interface Protocol Process
Call Reestablishment
O&M of BSC
BSC Local Switch
BTS Local Switch
BSC Local Switch
BTS Local Switch
BSC Local Switch
BTS Local Switch
BSC Local Switch
BTS Local Switch
BSC Local Switch
BTS Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BSC Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
BTS Local Switch
Fast Move Handover
Radio Common Channel Management
Location Updating
Board Switchover
MSRD
MSRD
O&M of BTS
HUAWEI I Handover
HUAWEI II Handover
Network-Controlled Cell Reselection (NC2)
Gb Interface Function
BSC Node Redundancy
GPRS
None
GSM Flow Control
None
A Interface Protocol Process
None
A over IP
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
O&M of BTS
GPRS
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
Abis IP over E1/T1
A IP over E1/T1
None
Abis MUX
UDP MUX for A Transmission
O&M of BTS
Abis MUX
UDP MUX for A Transmission
Ring Topology
Radio Link Management
Radio Link Management
Radio Link Management
Radio Link Management
Radio Link Management
Radio Link Management
Radio Link Management
GPRS
GPRS
GPRS
Dynamically Adjusting the RRBP Frequency
Gb Over FR
Gb Over FR
Gb Over FR
Network Assisted Cell Change (NACC)
PS Handover
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
IP QOS
A over IP
A over IP
A over IP
A over IP
A over IP
GPRS
Enhanced Channel Assignment Algorithm
Power Control
AMR FR
AMR HR
Configuration Management
IBCA (Interference Based Channel Allocation)
Configuration Management
IBCA (Interference Based Channel Allocation)
Configuration Management
Configuration Management
Configuration Management
Configuration Management
PICO Automatic Configuration and Planning
Configuration Management
Configuration Management
Configuration Management
Configuration Management
Network-Controlled Cell Reselection (NC2)
Network Assisted Cell Change (NACC)
Network-Controlled Cell Reselection (NC2)
Network-Controlled Cell Reselection (NC2)
PS Handover
Configuration Management
Configuration Management
Basic Cell Selection
Basic Cell Re-selection
Processing of Measurement Report
Pre-processing of Measurement Report
Fast Move Handover
HUAWEI I Handover
HUAWEI II Handover
2G/3G Neighboring Cell Automatic Optimization
2G/3G Neighboring Cell Automatic Optimization
2G/3G Neighboring Cell Automatic Optimization
2G/3G Neighboring Cell Automatic Optimization
2G/3G Neighboring Cell Automatic Optimization
2G/3G Neighboring Cell Automatic Optimization
2G/3G Neighboring Cell Automatic Optimization
2G/3G Neighboring Cell Automatic Optimization
Public Voice Group Call Service
Public Voice Broadcast Service
Public Voice Group Call Service
Public Voice Broadcast Service
Networking Control Mode
GSM/TD-SCDMA Interoperability
A Interface Protocol Process
Configuration Management
HUAWEI I Handover
HUAWEI II Handover
None
None
None
Abis IP over E1/T1
A Interface Protocol Process
BSC/RNC Software Management
Network Operation Mode Support
DTM
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
HUAWEI II Handover
Ater Compression Transmission
IP QOS
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
O&M of BTS
HUAWEI III Power Control Algorithm
Networking Control Mode
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Network-Controlled Cell Reselection (NC2)
O&M of BTS
GSM Flow Control
Radio Dedicated Channel Management
Group Call Reliability Enhancing
None
Enhanced Measurement Report(EMR)
Enhanced Measurement Report(EMR)
MSC Pool
SGSN Pool
SGSN Pool
System Information Sending
Gb Interface Function
Gb Interface Function
HUAWEI I Handover
HUAWEI II Handover
BSS-Based LCS (Cell ID + TA)
Soft-Synchronized Network
Gb Over FR
Gb Over FR
O&M of BTS
O&M of BTS
Public Voice Group Call Service
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
IP QOS
O&M of BTS
O&M of BTS
Link aggregation
O&M of BTS
O&M of BTS
Link aggregation
Remote Electrical Tilt
BTS Test Function
O&M of BSC
None
Faulty Management
Faulty Management
Configuration Management
Streaming QoS(GBR)
Concentric Cell
OML Backup
O&M of BTS
Abis Bypass
O&M of BTS
O&M of BTS
O&M of BTS
None
IP QOS
O&M of BTS
Abis over IP
O&M of BTS
O&M of BTS
O&M of BSC
Security Management
Configuration Management
RAN Sharing
O&M of BTS
A Interface Circuit Management
RAN Sharing
RAN Sharing
RAN Sharing
BSC/RNC Software Management
A Interface Circuit Management
Ater Interface 4:1 Multiplexing
A Interface Circuit Management
O&M of BSC
RAN Sharing
Concentric Cell
Concentric Cell
Concentric Cell
Enhanced Channel Assignment Algorithm
O&M of BTS
O&M of BTS
O&M of BTS
MBSC Load Balancing
IP-Based 2G/3G Co-Transmission on Base Station Side
BSC/RNC Software Management
Frequency Band
EGPRS
Concentric Cell
Enhanced Dual-Band Network
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
Enhanced Dual-Band Network
Enhanced Channel Assignment Algorithm
Enhanced Dual-Band Network
Enhanced Dual-Band Network
Enhanced Dual-Band Network
Enhanced Dual-Band Network
Enhanced Dual-Band Network
Enhanced Dual-Band Network
Semi-Permanent Connection
Semi-Permanent Connection
O&M of BSC
O&M of BSC
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Multi-site Cell
Multi-site Cell
Multi-site Cell
Enhanced Dual-Band Network
O&M of BTS
Semi-Permanent Connection
O&M of BSC
Semi-Permanent Connection
GSM and UMTS Load Balancing Based on Iur-g
GSM/WCDMA Service Based Handover
GSM/WCDMA Service Based Handover
MBSC Load Balancing
Semi-Permanent Connection
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Radio Common Channel Management
O&M of BTS
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
Multi-Carrier Intelligent Voltage Regulation
Packet Assignment Taken Over by the BTS
GSM Flow Control
Paging
GSM Flow Control
Paging
GPRS
GPRS
GPRS
TRX Power Amplifier Intelligent Shutdown
O&M of BTS
O&M of BTS
IP QOS
Abis over IP
A over IP
None
Active Power Control
HUAWEI II Handover
Abis over IP
A over IP
BSC/RNC Software Management
Power Control
HUAWEI I Handover
HUAWEI I Handover
HUAWEI I Handover
HUAWEI I Handover
GPRS
Enhanced Power Control Algorithm
Power Control
O&M of BSC
GPRS
O&M of BSC
GPRS
O&M of BTS
Flex Abis
GPRS
PDCH Dynamic Adjustment
Power Optimization Based on Channel Type
PDCH Dynamic Adjustment
Load Sharing
GPRS
PDCH Dynamic Adjustment
A over IP
A IP over E1/T1
BSC Node Redundancy
Abis over IP
Abis over IP
BSC Node Redundancy
Abis over IP
BSC Node Redundancy
Abis over IP
BSC Node Redundancy
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
IP Fault Detection Based on BFD
Abis IP over E1/T1
Abis IP over E1/T1
A over IP
A IP over E1/T1
A over IP
A IP over E1/T1
IP QOS
Abis over IP
A over IP
A over IP
A IP over E1/T1
O&M of BTS
HUAWEI I Handover
HUAWEI II Handover
Network-Controlled Cell Reselection (NC2)
Network-Controlled Cell Reselection (NC2)
HUAWEI I Handover
HUAWEI II Handover
IP QOS
2G/3G Neighboring Cell Automatic Optimization
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
Streaming QoS(GBR)
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
IP QOS
Abis MUX
UDP MUX for A Transmission
Basic Cell Re-selection
System Information Sending
Security Management
Ethernet OAM
Ethernet OAM
None
Abis MUX
Packet SI Status
None
Ethernet OAM
Access
EGPRS
Access
Access
EGPRS
Access
EGPRS
IP QOS
IP QOS
O&M of BSC
O&M of BSC
O&M of BSC
GSM Flow Control
GSM Flow Control
Paging
Paging
Paging
GSM Flow Control
GSM Flow Control
GSM Flow Control
Configuration Management
Faulty Management
Configuration Management
Ater Interface 4:1 Multiplexing
A Interface Circuit Management
None
O&M of BSC
Faulty Management
None
None
None
None
None
Board Switchover
None
None
None
None
IP Fault Detection Based on BFD
None
None
Gb Over FR
O&M of BSC
O&M of BTS
Faulty Management
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
PoC QoS
PoC QoS
PoC QoS
PoC QoS
O&M of BTS
O&M of BTS
Configuration Management
Configuration Management
O&M of BSC
Ring Topology
OML Backup
O&M of BSC
O&M of BSC
None
Configuration Management
Ethernet OAM
IP-Based 2G/3G Co-Transmission on Base Station Side
2G/3G Cell Reselection Based on MS State
O&M of BTS
O&M of BTS
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
O&M of BTS
Downlink EGPRS2-A
Downlink EGPRS2-A
O&M of BTS
O&M of BTS
Configuration Management
Configuration Management
Abis IP over E1/T1
Abis IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
None
Abis IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
None
Enhanced Multi Level Precedence and Preemption(EMLPP)
Enhanced Multi Level Precedence and Preemption(EMLPP)
Emergency Call Service (TS12)
Guaranteed Emergency Call
Pre-processing of Measurement Report
Abis over IP
System Information Sending
GPRS
GSM Flow Control
Pre-processing of Measurement Report
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
Flex Abis
GPRS
A Interface Protocol Process
A over IP
A Interface Protocol Process
A over IP
None
Abis over IP
Abis over IP
Abis over IP
Security Management
Abis over IP
A Interface Protocol Process
Gb Over FR
O&M of BTS
Dynamic Cell Power Off
TRX Power Amplifier Intelligent Shutdown
None
None
None
None
None
None
None
None
IP QOS
IP QOS
PS Handover
None
None
GSM Flow Control
System Information Sending
Packet System Information
Packet System Information
IP QOS
IP QOS
GSM Flow Control
Concentric Cell
None
Radio Common Channel Management
Multi-site Cell
None
GSM Flow Control
GSM Flow Control
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Concentric Cell
PSU Smart Control
None
Faulty Management
O&M of BSC
Basic Cell Re-selection
Gb Interface Function
Faulty Management
None
None
None
None
Abis Transmission Optimization
None
O&M of BTS
Security Management
O&M of BTS
O&M of BTS
Gb Over FR
Security Management
O&M of BSC
Security Management
O&M of BTS
Security Management
O&M of BTS
Faulty Management
Faulty Management
Active Power Control
HUAWEI III Power Control Algorithm
Enhanced Power Control Algorithm
Radio Common Channel Management
Radio Common Channel Management
Multi-site Cell
O&M of BTS
Active Backup Power Control
Enhanced Channel Assignment Algorithm
Configuration Management
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
O&M of BTS
Connection with TMA (Tower Mounted Amplifier)
O&M of BTS
None
None
None
None
None
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
QoS ARP&THP
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
Enhanced Channel Assignment Algorithm
O&M of BTS
O&M of BTS
Enhanced Power Control Algorithm
HUAWEI I Handover
HUAWEI II Handover
Fast Move Handover
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Configuration Management
Configuration Management
GPRS
Compact BTS Automatic Configuration and Planning
Compact BTS Automatic Configuration and Planning
Compact BTS Automatic Capacity Planning
Radio Common Channel Management
Radio Common Channel Management
Radio Common Channel Management
Multi-site Cell
System Information Sending
GPRS
GPRS
Radio Common Channel Management
GPRS
Abis over IP
AMR Coding Rate Threshold Adaptive Adjustment
WB AMR
AMR Coding Rate Threshold Adaptive Adjustment
TFO
Processing of Measurement Report
Configuration Management
O&M of BSC
O&M of BTS
O&M of BTS
O&M of BTS
Configuration Management
IP QOS
TCH Re-assignment
TCH Re-assignment
Concentric Cell
AMR FR
Concentric Cell
AMR HR
Concentric Cell
Concentric Cell
Concentric Cell
GSM Flow Control
IP QOS
Concentric Cell
Concentric Cell
Configuration Management
GSM Flow Control
GSM Flow Control
BSC/RNC Clock
BSC/RNC Clock
BSC/RNC Clock
BSC/RNC Clock
BSC/RNC Clock
BSC/RNC Clock
BSC/RNC Clock
BTS Local Switch
BSC Node Redundancy
BSC Node Redundancy
BSC Node Redundancy
Soft-Synchronized Network
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
IP QOS
None
Gb over IP
Simplified Cell Broadcast
Robust Air Interface Signalling
Robust Air Interface Signalling
Robust Air Interface Signalling
Faulty Management
O&M of BSC
Network-Controlled Cell Reselection (NC2)
Network-Controlled Cell Reselection (NC2)
Network-Controlled Cell Reselection (NC2)
Network-Controlled Cell Reselection (NC2)
PDCH Dynamic Adjustment
TRX Power Amplifier Intelligent Shutdown
O&M of BTS
O&M of BTS
Security Management
GPRS
Multi-Carrier Intelligent Voltage Regulation
GPRS
Gb Interface Function
A Interface Protocol Process
O&M of BSC
License Management
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Faulty Management
MBSC Load Balancing
Resource Reservation
Configuration Management
Radio Dedicated Channel Management
System Information Sending
O&M of BSC
Voice Fault Diagnosis
BTS GPS Synchronization
Network Assisted Cell Change (NACC)
None
Radio Dedicated Channel Management
Ater Compression Transmission
Configuration Management
MBSC Load Balancing
MBSC Load Balancing
MBSC Load Balancing
Security Management
Gb over IP
Gb over IP
Voice Quality Index (Uplink VQI)
Networking Control Mode
Networking Control Mode
GSM/TD-SCDMA Interoperability
IP QOS
Voice Quality Index (Uplink VQI)
Enhanced Measurement Report(EMR)
Enhanced Measurement Report(EMR)
IP QOS
None
IP QOS
HUAWEI I Handover
HUAWEI II Handover
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
None
None
GPRS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Abis over IP
Configuration Management
2G/3G Neighboring Cell Automatic Optimization
BSC/RNC Software Management
O&M of BSC
A Interface Protocol Process
Abis IP over E1/T1
Emergency Call Service (TS12)
None
None
None
None
None
None
None
None
None
None
TRX Power Amplifier Intelligent Shutdown
Board Switchover
A over IP
A IP over E1/T1
A over IP
A over IP
None
None
Abis over IP
A over IP
A over IP
A over IP
A over IP
A over IP
AMR Coding Rate Threshold Adaptive Adjustment
Latency Reduction
Streaming QoS(GBR)
Abis over IP
IP QOS
IP QOS
O&M of BTS
IP QOS
IP QOS
GPRS
AMR FR
HUAWEI II Handover
System Information Sending
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
None
None
Remote EAC Maintenance
Faulty Management
O&M of BTS
Public Voice Group Call Service
Network Support SAIC
Network Support SAIC
Network Support SAIC
Faulty Management
Dynamic Cell Power Off
Dynamic Cell Power Off
Dynamic Cell Power Off
Dynamic Cell Power Off
Dynamic Cell Power Off
Radio Dedicated Channel Management
Faulty Management
Remote EAC Maintenance
Faulty Management
Remote EAC Maintenance
Faulty Management
O&M of BTS
O&M of BTS
Soft-Synchronized Network
Soft-Synchronized Network
Enhanced Measurement Report(EMR)
Gb over IP
Fast Move Handover
Configuration Management
O&M of BTS
Simplified Cell Broadcast
O&M of BTS
O&M of BSC
O&M of BSC
O&M of BSC
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
Faulty Management
A over IP
A IP over E1/T1
O&M of BSC
Faulty Management
Faulty Management
Faulty Management
Board Switchover
O&M of BTS
Support of Daylight Saving Time
Configuration Management
Configuration Management
Assignment and Immediate Assignment
Assignment and Immediate Assignment
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
SDCCH Dynamic Adjustment
Board Switchover
A5/3 Ciphering Algorithm
Active Backup Power Control
HUAWEI I Handover
HUAWEI II Handover
HUAWEI III Power Control Algorithm
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
Gb over IP
Board Switchover
O&M of BTS
BTS Power Management
Faulty Management
Faulty Management
O&M of BTS
Enhanced Measurement Report(EMR)
O&M of BTS
System Information Sending
End-to-End MS Signaling Tracing
HUAWEI I Handover
HUAWEI II Handover
A Interface Protocol Process
Point To Point Short Message Service (TS21, TS22)
Group Call EMLPP
Group Call EMLPP
Multi-Carrier Intelligent Voltage Regulation
System Information Sending
System Information Sending
System Information Sending
O&M of BTS
O&M of BTS
O&M of BSC
O&M of BSC
Remote Electrical Tilt
O&M of BSC
A over IP
TC Pool
Abis over IP
PICO Automatic Configuration and Planning
O&M of BSC
Security Management
Abis over IP
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
SGSN Pool
Configuration Management
SGSN Pool
SGSN Pool
SGSN Pool
GPRS
SGSN Pool
GSM Flow Control
O&M of BSC
RAN Sharing
Faulty Management
Active Backup Power Control
System Information Sending
HUAWEI I Handover
HUAWEI II Handover
Soft-Synchronized Network
A Interface Protocol Process
A Interface Protocol Process
A over IP
Gb over IP
Gb over IP
IP QOS
Soft-Synchronized Network
HUAWEI I Handover
HUAWEI II Handover
A Interface Protocol Process
Local Multiple Signaling Points
HUAWEI I Handover
HUAWEI II Handover
Load Sharing
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
None
None
O&M of BSC
Soft-Synchronized Network
Clock over IP
Multi-site Cell
BTS Test Function
A Interface Protocol Process
BSC Node Redundancy
Support of Daylight Saving Time
Configuration Management
None
None
Faulty Management
Support of Daylight Saving Time
Configuration Management
Flow Control
Configuration Management
Configuration Management
None
A over IP
None
None
O&M of BSC
Faulty Management
Faulty Management
None
None
Configuration Management
MBSC Load Balancing
O&M of BTS
IP Fault Detection Based on BFD
Configuration Management
O&M of BSC
O&M of BTS
O&M of BTS
O&M of BTS
Configuration Management
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BSC
14-Digit Signaling Point Code
A Interface Protocol Process
14-Digit Signaling Point Code
A Interface Protocol Process
14-Digit Signaling Point Code
A Interface Protocol Process
O&M of BSC
A Interface Protocol Process
Radio Common Channel Management
Location Updating
Faulty Management
Faulty Management
Voice Fault Diagnosis
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
Group Call Reliability Enhancing
Group Call Reliability Enhancing
Group Call Reliability Enhancing
None
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
System Information Sending
Discontinuous Reception (DRX)
Short Message Service Cell Broadcast (TS23)
MBSC Load Balancing
MBSC Load Balancing
PS Handover
PS Handover
Network Assisted Cell Change (NACC)
Public Voice Group Call Service
GPRS
GPRS
GPRS
GPRS
RAN Sharing
Latency Reduction
RAN Sharing
O&M of BSC
A Interface Protocol Process
O&M of BTS
O&M of BTS
O&M of BTS
HUAWEI I Handover
HUAWEI II Handover
Configuration Management
Configuration Management
Configuration Management
Configuration Management
O&M of BSC
BSC/RNC Clock
BSC/RNC Clock
HUAWEI I Handover
HUAWEI II Handover
IP Fault Detection Based on BFD
Configuration Management
Configuration Management
None
Configuration Management
None
BSC/RNC Clock
None
Configuration Management
Configuration Management
None
None
A over IP
None
None
Faulty Management
None
Configuration Management
MBSC Load Balancing
O&M of BTS
IP Fault Detection Based on BFD
Configuration Management
O&M of BSC
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BSC
O&M of BSC
Configuration Management
O&M of BTS
BSC/RNC Clock
Faulty Management
Gb over IP
Gb over IP
O&M of BTS
Intelligent Shutdown of TRX Due to PSU Failure
IP QOS
HUAWEI I Handover
HUAWEI II Handover
Faulty Management
Faulty Management
Faulty Management
Faulty Management
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
Configuration Management
MBSC Load Balancing
Faulty Management
HUAWEI I Handover
HUAWEI II Handover
Support of Daylight Saving Time
Configuration Management
O&M of BSC
O&M of BSC
O&M of BSC
Security Management
Faulty Management
Faulty Management
Simplified Cell Broadcast
Faulty Management
Frequency Hopping (RF hopping, baseband hopping)
GSM Flow Control
A Interface Circuit Management
O&M of BSC
TRX Power Amplifier Intelligent Shutdown
O&M of BTS
TRX Power Amplifier Intelligent Shutdown
GSM Flow Control
GSM Flow Control
O&M of BTS
Group Call Reliability Enhancing
TRX Power Amplifier Intelligent Shutdown
Ater Interface 4:1 Multiplexing
A Interface Circuit Management
O&M of BTS
O&M of BTS
O&M of BTS
A Interface Circuit Management
O&M of BTS
O&M of BSC
Security Management
2G/3G Neighboring Cell Automatic Optimization
A Interface Protocol Process
O&M of BTS
EICC
A5/1 Encryption Flow Optimization
Group Call Reliability Enhancing
A Interface Protocol Process
Semi-Permanent Connection
Cell Frequency Scan
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BSC
Security Management
O&M of BTS
O&M of BTS
TC Pool
TC Pool
O&M of BTS
Abis MUX
UDP MUX for A Transmission
Abis MUX
O&M of BSC
None
Flex Abis
Flex Abis
O&M of BSC
O&M of BTS
A Interface Circuit Management
BSC/RNC Clock
BSC/RNC Clock
Simplified Cell Broadcast
PDCH Dynamic Adjustment
MS High multislot classes
DTM
PDCH Dynamic Adjustment
EDA(Extended Dynamic Allocation)
DTM
BTS Local Switch
TFO
MBSC Handover based on Load Enhancement
Access
Gb over IP
Gb over IP
Faulty Management
O&M of BSC
O&M of BSC
O&M of BTS
O&M of BTS
Support of Daylight Saving Time
Configuration Management
Configuration Management
None
License Management
IP Fault Detection Based on BFD
O&M of BTS
AMR FR
AMR HR
A over IP
A over IP
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BTS
O&M of BSC
Security Management
Support of Daylight Saving Time
Configuration Management
Soft-Synchronized Network
GSM/TD-SCDMA Interoperability
IBCA (Interference Based Channel Allocation)
Soft-Synchronized Network
Clock over IP
Clock over IP
Clock over IP
Clock over IP
Configuration Management
Configuration Management
HUAWEI I Handover
HUAWEI II Handover
Configuration Management
Public Voice Group Call Service
Configuration Management
Configuration Management
Gb Interface Function
Abis over IP
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
Gb Interface Function
Abis over IP
Ring Topology
Radio Link Management
Radio Link Management
Radio Link Management
Radio Link Management
Radio Link Management
Radio Link Management
Radio Link Management
Fast Ring Network Switch
A Interface Protocol Process
A Interface Protocol Process
A Interface Protocol Process
Gb Interface Function
Abis over IP
HUAWEI I Handover
HUAWEI II Handover
Public Voice Broadcast Service
GPRS
GPRS
Location Updating
Gb Over FR
A Interface Protocol Process
Gb Interface Function
A Interface Protocol Process
Gb Interface Function
A Interface Protocol Process
Gb Interface Function
Gb Interface Function
A Interface Protocol Process
HUAWEI I Handover
HUAWEI II Handover
Concentric Cell
HUAWEI I Handover
HUAWEI II Handover
Concentric Cell
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
Talker Identification
HUAWEI I Handover
HUAWEI II Handover
Soft-Synchronized Network
HUAWEI II Handover
Concentric Cell
Power Control
Power Control
O&M of BSC
O&M of BTS
OML Backup
Ring Topology
A Interface Protocol Process
Gb Interface Function
O&M of BTS
O&M of BSC
TC Pool
Dynamic Adjustment Between FR and HR
Enhanced Channel Assignment Algorithm
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
Radio Dedicated Channel Management
HUAWEI I Handover
HUAWEI II Handover
HUAWEI III Power Control Algorithm
Enhanced Channel Assignment Algorithm
A5/1 Encryption Flow Optimization
A5/1 Encryption Flow Optimization
Concentric Cell
Concentric Cell
A Interface Protocol Process
A Interface Protocol Process
O&M of BSC
O&M of BTS
None
TC Pool
None
None
Configuration Management
GSM/TD-SCDMA Interoperability
Configuration Management
GSM/TD-SCDMA Interoperability
GSM/TD-SCDMA Interoperability
GSM/TD-SCDMA Interoperability
GSM/TD-SCDMA Interoperability
GSM/TD-SCDMA Interoperability
GSM/TD-SCDMA Interoperability
GSM/TD-SCDMA Interoperability
GSM/TD-SCDMA Interoperability
GSM/TD-SCDMA Interoperability
Configuration Management
GSM/TD-SCDMA Interoperability
GSM/TD-SCDMA Interoperability
IP QOS
IP QOS
O&M of BSC
O&M of BSC
O&M of BSC
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
O&M of BTS
Configuration Management
Configuration Management
Configuration Management
Configuration Management
O&M of BTS
BTS Power Management
O&M of BTS
O&M of BTS
System Information Sending
Gb Interface Function
Simplified Cell Broadcast
TFO
BTS Test Function
Configuration Management
O&M of BSC
None
None
None
None
None
GPRS
O&M of BTS
O&M of BTS
QoS ARP&THP
QoS ARP&THP
QoS ARP&THP
QoS ARP&THP
QoS ARP&THP
QoS ARP&THP
QoS ARP&THP
QoS ARP&THP
QoS ARP&THP
IP QOS
SGSN Pool
BCCH Dense Frequency Multiplexing
BCCH Dense Frequency Multiplexing
BCCH Dense Frequency Multiplexing
BCCH Dense Frequency Multiplexing
BCCH Dense Frequency Multiplexing
BCCH Dense Frequency Multiplexing
BCCH Dense Frequency Multiplexing
IBCA (Interference Based Channel Allocation)
MSC Pool
O&M of BSC
Security Management
O&M of BSC
Cell Frequency Scan
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
Concentric Cell
Ethernet OAM
Ethernet OAM
Ethernet OAM
Ethernet OAM
Abis MUX
HUAWEI I Handover
HUAWEI II Handover
None
Power Optimization Based on Channel Type
HUAWEI I Handover
HUAWEI II Handover
Concentric Cell
Enhanced Channel Assignment Algorithm
MSC Pool
O&M of BSC
Security Management
GPRS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
O&M of BSC
IP QOS
None
None
BTS Test Function
Call Control
Faulty Management
O&M of BSC
Faulty Management
A Interface Protocol Process
A Interface Protocol Process
Configuration Management
Satellite Transmission over Ater Interface
O&M of BSC
Support of Daylight Saving Time
Configuration Management
Basic Cell Re-selection
IP-Based 2G/3G Co-Transmission on Base Station Side
IP-Based 2G/3G Co-Transmission on Base Station Side
IP-Based 2G/3G Co-Transmission on Base Station Side
O&M of BSC
O&M of BTS
HUAWEI I Handover
HUAWEI II Handover
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
Adaptive Adjustment of Uplink and Downlink Channels
Adaptive Adjustment of Uplink and Downlink Channels
A over IP
Satellite Transmission over Abis Interface
O&M of BSC
IP QOS
IP QOS
IP QOS
O&M of BTS
Abis over IP
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
GPRS
HUAWEI I Handover
HUAWEI II Handover
Link aggregation
Link aggregation
Link aggregation
O&M of BTS
IP QOS
None
None
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
IP QOS
None
O&M of BTS
None
IP Fault Detection Based on BFD
Ethernet OAM
TRX Cooperation
BTS Test Function
Frequency Hopping (RF hopping, baseband hopping)
Configuration Management
Multi-site Cell
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Antenna Frequency Hopping
Frequency Hopping (RF hopping, baseband hopping)
BTS Test Function
Frequency Hopping (RF hopping, baseband hopping)
Configuration Management
O&M of BTS
O&M of BTS
Multi-site Cell
Enhanced Channel Assignment Algorithm
O&M of BTS
Ater Interface 4:1 Multiplexing
A Interface Circuit Management
None
Gb Over FR
O&M of BSC
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
A IP over E1/T1
Abis IP over E1/T1
Frequency Hopping (RF hopping, baseband hopping)
GPRS
Flex Abis
Soft-Synchronized Network
None
BTS Test Function
Semi-Permanent Connection
O&M of BSC
Configuration Management
IP-Based 2G/3G Co-Transmission on Base Station Side
O&M of BTS
O&M of BSC
Enhanced Channel Assignment Algorithm
Enhanced Channel Assignment Algorithm
Adaptive Adjustment of Uplink and Downlink Channels
Adaptive Adjustment of Uplink and Downlink Channels
Semi-Permanent Connection
O&M of BTS
BTS Test Function
O&M of BTS
BTS Test Function
O&M of BTS
TRX Power Amplifier Intelligent Shutdown on Timeslot Level
O&M of BTS
None
None
Dynamic Cell Power Off
Dynamic Cell Power Off
Dynamic Cell Power Off
Dynamic Cell Power Off
Dynamic Cell Power Off
O&M of BTS
O&M of BTS
Soft-Synchronized Network
Soft-Synchronized Network
Soft-Synchronized Network
Soft-Synchronized Network
Soft-Synchronized Network
Soft-Synchronized Network
Soft-Synchronized Network
Radio Common Channel Management
Location Updating
RAN Sharing
RAN Sharing
RAN Sharing
RAN Sharing
RAN Sharing
RAN Sharing
RAN Sharing
RAN Sharing
IP QOS
IP QOS
None
Access
Configuration Management
O&M of BSC
Frequency Band
GPRS
Compact BTS Automatic Configuration and Planning
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
A over IP
Enhanced Channel Assignment Algorithm
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
Abis over IP
A over IP
Abis MUX
UDP MUX for A Transmission
Abis MUX
UDP MUX for A Transmission
Gb over IP
Gb over IP
O&M of BSC
Security Management
O&M of BTS
Public Voice Group Call Service
Public Voice Broadcast Service
None
Faulty Management
Faulty Management
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI II Handover
HUAWEI II Handover
Adaptive Adjustment of Uplink and Downlink Channels
O&M of BSC
RLC Mode
HUAWEI I Handover
HUAWEI II Handover
RLC Mode
RLC Mode
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
AMR FR
AMR FR
AMR FR
AMR HR
AMR HR
AMR HR
WB AMR
WB AMR
GSM and UMTS Load Balancing Based on Iur-g
Enhanced Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
GSM and UMTS Load Balancing Based on Iur-g
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
HUAWEI I Handover
HUAWEI II Handover
AMR FR
HUAWEI II Handover
AMR HR
HUAWEI II Handover
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
HUAWEI III Power Control Algorithm
Enhanced Power Control Algorithm
Enhanced Power Control Algorithm
AMR FR
WB AMR
AMR FR
WB AMR
AMR FR
WB AMR
AMR HR
AMR HR
AMR HR
WB AMR
WB AMR
Concentric Cell
RLC Mode
O&M of BSC
HUAWEI I Handover
HUAWEI II Handover
Configuration Management
None
Gb Over FR
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
Connection with TMA (Tower Mounted Amplifier)
Faulty Management
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Simplified Cell Broadcast
GPRS
Coding Scheme
EGPRS
Coding Scheme
GPRS
PDCH Dynamic Adjustment
Uplink EGPRS2-A
Uplink EGPRS2-A
Extended Uplink TBF
GPRS
Coding Scheme
EGPRS
Coding Scheme
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
Group Call Reliability Enhancing
Abis over IP
Enhanced Power Control Algorithm
HUAWEI III Power Control Algorithm
IP QOS
None
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
HUAWEI I Handover
HUAWEI II Handover
Point To Point Short Message Service (TS21, TS22)
Extended Uplink TBF
Coding Scheme
CS-3/CS-4
Coding Scheme
CS-3/CS-4
Coding Scheme
Coding Scheme
CS-3/CS-4
Coding Scheme
CS-3/CS-4
Coding Scheme
Network-Controlled Cell Reselection (NC2)
O&M of BSC
GPRS
O&M of BSC
License Management
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Concentric Cell
Concentric Cell
Concentric Cell
Concentric Cell
Concentric Cell
Concentric Cell
GSM/WCDMA Interoperability
GSM/TD-SCDMA Interoperability
O&M of BTS
Public Voice Group Call Service
Public Voice Broadcast Service
Public Voice Group Call Service
Public Voice Broadcast Service
Public Voice Group Call Service
Public Voice Broadcast Service
GSM Flow Control
GSM Flow Control
GSM Flow Control
GSM Flow Control
IP QOS
None
None
None
Abis IP over E1/T1
A IP over E1/T1
Ethernet OAM
Abis over IP
Ethernet OAM
Configuration Management
None
None
None
Abis over IP
Abis over IP
Configuration Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
Faulty Management
O&M of BTS
Faulty Management
Faulty Management
Faulty Management
O&M of BTS
O&M of BTS
Call Control
AMR FR
AMR HR
None
Emergency Call Service (TS12)
Guaranteed Emergency Call
IBCA (Interference Based Channel Allocation)
None
O&M of BTS
Faulty Management
O&M of BSC
Security Management
BSS-Based LCS (Cell ID + TA)
Soft-Synchronized Network
O&M of BTS
IP Fault Detection Based on BFD
Abis over IP
O&M of BSC
Security Management
A over IP
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
O&M of BTS
Configuration Management
O&M of BTS
Configuration Management
None
O&M of BTS
O&M of BSC
OML Backup
Ring Topology
Board Switchover
Support of Daylight Saving Time
Configuration Management
Value Type GUI Value Range
Interval Type 0~70
Interval Type 0~70
Interval Type 10~80
Enumeration
Type TRUE(Support), FALSE(Not Support)
Enumeration
Type NO(No), YES(Yes)
Interval Type 10~255
Interval Type 10~255
Enumeration IDLETSALLOC_0(Any idle timeslots under the same site),
Type IDLETSALLOC_1(Idle timeslots on same E1 primary link
Enumeration
Type CLOSE(CLOSE), OPEN(OPEN)
Interval Type 0~100
Enumeration
Type NO(NO), YES(YES)
Interval Type 10~3600
Enumeration
Type GSM_PHASE_1, GSM_PHASE_2, GSM_PHASE_2Plus
Interval Type 1~255
Interval Type 0~250
Enumeration
Type 8BIT(8BIT), 11BIT(11BIT)
Interval Type 0~65535
Enumeration
Type NO(No), YES(Yes)
Interval Type 0~31
Enumeration OSubcell(Overlaid subcell), USubcell(Underlaid subcell),
Type NoPrefer(No preference)
Interval Type 0~31
Enumeration ULPRIORITY(Uplink Priority), NEUTRAL(Neutral Priority),
Type DLPRIORITY(Downlink Priority)
Interval Type 0~9
Interval Type 1~10
Interval Type 15~7200
Enumeration
Type Disable(Disable), Enable(Enable)
Enumeration
Type NO(No), YES(Yes)
Enumeration
Type CLOSE(Close), OPEN(Open)
Enumeration COMPUL0(Compulsory 0), COMPUL1(Compulsory 1),
Type FLEX(Flexible)
4_75KBIT/S~0 5_15KBIT/S~1 5_90KBIT/S~2
Bit Field Type 6_70KBIT/S~3 7_40KBIT/S~4 7_95KBIT/S~5
4_75KBIT/S~0 5_15KBIT/S~1 5_90KBIT/S~2
Bit Field Type 6_70KBIT/S~3 7_40KBIT/S~4 7_95KBIT/S
Bit Field Type 6_60KBIT/S, 8_85KBIT/S, 12_65KBIT/S
Enumeration
Type NO(No), YES(Yes)
Interval Type 1~255
Interval Type 60~300
Interval Type 610~3000
Interval Type 600~2990
Interval Type 60~300
Enumeration
Type NO(No), YES(Yes)
Interval Type 0~254
Interval Type 0~50
Interval Type 0~768
Bit Field Type PORT0_CDEF, PORT1_CDEF
Interval Type 1~16777215
Enumeration
Type BYMANUAL(By Manual), BYAUTO(By Auto)
Enumeration 0(Not support dynamic adjustment), 1(According to downlink
Type quality measurements reported by MS), 2(According to
Enumeration
Type OFF(OFF), ON(ON)
Enumeration COMMON_DLD(Common Download), QUICK_DLD1(Quick
Type Download No Traffic), QUICK_DLD2(Quick Download
Enumeration
Type LOCK(Lock), UNLOCK(Unlock), SHUTDOWN(Shutdown)
Enumeration
Type Lock(Lock), Unlock(Unlock), Shutdown(S