Tasks by tyndale

VIEWS: 24 PAGES: 78

									Task_ID                        Task                          Topic              Speciality                       Description
  1       Experimental tests of compact optics            Beam Tests      Accelerator Physics    FF tests – at ATF / CLIC-3 / SLAC-line A/B
          Electrostatic separator experimental tests in
  2       harsh environment, up to 500 GeV/beam,          Beam Tests      Experimental Physics
          feasibility and reliability
          Experimental verification of backscattered
  3       photons in multi-bunch accelerator              Beam Tests      Experimental Physics
          environment
          Experimental verification of photon-photon
  4                                                       Beam Tests      Experimental Physics
          collisions
  5       Collimator material damage tests                Beam Tests      Experimental Physics
  6       Collimator wakefield tests                      Beam Tests      Experimental Physics

  7       BPM tests in IR-like environment                Beam Tests      Experimental Physics   ESA beam tests within 2-3 years from now


  8       Pair monitor prototype beam test in ESA         Beam Tests      Experimental Physics

   9      Prototype IR in ESA                             Beam Tests      Experimental Physics   at SLAC/ESA? By SLAC, UK ?
  10      BPM tests at ESA and ATF                        Beam Tests      Experimental Physics
          Develop “disrupted” and “pairs” beam
  11                                                      Beam Tests      Experimental Physics
          capability at ESA
  12      EMI Test of VXD and Detector electronics        Beam Tests      Experimental Physics
                                                          Collimation &
  13      Collimation Study                                               Accelerator Physics    MARS, STRUCT, GEANT, other
                                                            Bkgnds
                                                          Collimation &
  14      Tail-folding study                                              Accelerator Physics
                                                            Bkgnds
                                                          Collimation &
  15      Collimation system performance study                            Accelerator Physics    MARS, STRUCT, GEANT, other
                                                            Bkgnds
          Re-estimate of beam halo and decision on
                                                          Collimation &
  16      halo/beam fraction collimation system and                       Accelerator Physics    MARS, STRUCT, other
                                                            Bkgnds
          shielding will be designed to handle
                                                                                                 Re-evaluate need for muon shielding in ILC
                                                          Collimation &
  17      Muon backgrounds                                                HEP Simulation         context considering detector and PPS issues
                                                            Bkgnds
                                                                                                 using MuCarlo, MARS, Struct, GEANT, other
Task_ID                         Task                         Topic               Speciality                         Description
          Study backgrounds caused by main beam and
                                                          Collimation &
  18      halo as a function of crossing angle and                        HEP Simulation           MARS, STRUCT, GEANT, other
                                                            Bkgnds
          extraction scheme
                                                          Collimation &
  19      Septum damage and background studies                            HEP Simulation           MARS, STRUCT, GEANT, other
                                                            Bkgnds
                                                                                                   Improved studies of QSR or direct beam loss
                                                                                                   when LC is operating in non-optimal mode;
          Detector background analyses: Core Beam,        Collimation &                            Study backscattered QSR and its effect on
  20                                                                      HEP Simulation
          Halo & SR                                         Bkgnds                                 feedback BPM; Placement of compton IP at
                                                                                                   start of Energy collimation region & tracking of
                                                                                                   off energy electrons
          Recalculation of all detector backgrounds       Collimation &                            Pairs, beam gas, neutrons, SR using MARS,
  21                                                                      HEP Simulation
          once CDR version of IR Layouts are finalized      Bkgnds                                 STRUCT, GEANT, other

  22      Study of engineering layouts and conflicts      Engineering     Civil Engineering

          Develop & prototype Interferometric network
  23                                                      Engineering     Experimental Physics
          for specific areas (e.g. energy spectrometer)
                                                                                                   EGS, FLUKA, GEANT, MARS, STRUCT,
  24      Collimator material damage analysis             Engineering     HEP Simulation
                                                                                                   other
  25      Prototype collimators-exotic                    Engineering     Mechanical Engineering

  26      Prototype collimators-traditional               Engineering     Mechanical Engineering
          Engineering study/prototypes any auxiliary                                             KEK support tube R&D program,
          vibration suppression system that can                                                  FONT/FEATHER, Inertial Stabilization, Optical
  27                                                      Engineering     Mechanical Engineering
          substantially reduce risk due to relative                                              Stabilization; None of these needed in
          vibration of magnets                                                                   baseline model
          Engineering design & prototype BDS (not IR)
  28                                                      Engineering     Mechanical Engineering
          quad supports and movers
          Document lengths, part counts, power                                                     Required for communication with Technical
  29                                                      Engineering     System Engineering
          requirements for working BDIR model                                                      Support Groups (CF, ME, EE)
  30      Engineering study of compact SC quad            Final Doublet   Magnet Engineering
  31      Prototype of compact SC quad                    Final Doublet   Magnet Engineering
  32      Engineering study of compact PM quad            Final Doublet   Magnet Engineering
Task_ID                      Task                           Topic           Speciality                              Description
  33    Prototype of compact PM quad                     Final Doublet Magnet Engineering
        Engineering study of large aperture traditional
  34                                                     Final Doublet Magnet Engineering
        SC quad
        Prototype of large aperture traditional SC
  35                                                     Final Doublet Magnet Engineering
        quad
        Study of gamma-gamma backgrounds vs.
  36                                                    Gamma-Gamma HEP Simulation
        crossing angle
        Mechanical design of optical cavity for g-g
  37                                                    Gamma-Gamma Optical Engineering
        laser
  38     Experimental test of g-g drive laser             Gamma-Gamma Optical Engineering
         Experimental test of g-g mirror stability,
  39                                                      Gamma-Gamma Optical Engineering
         damage
  40     Experimental test of g-g optical cavity          Gamma-Gamma Optical Engineering
         Measurement of spin precession through
         existing bending magnets to extract the                                                   Proposal by Valery Telnov - Aims are the
         integrated bending field used is a                                                        same as for the upstream spectrometer - The
         spectrometre - The claim is that reduced                                                  feasibility of precise position measurements at
  41                                                      Instrumentation Accelerator Physics
         requirements on BPMs result because larger                                                large distances for absolute calibration needs
         bend angles and drifts can be used - A                                                    to be spelled out - Combining with polarimetry,
         prerequisite of this method is polarisation of                                            both up- and downstream should be studied
         both beams
                                                                                                   Use existing bends and plan mechanical or
                                                                                                   laser wires for beam size measurements -
         Track relative changes in energy distribution
  42                                                      Instrumentation Accelerator Physics      Initial study by Nick Walker - Needs to be
         by measuring the spent beam
                                                                                                   taken up, presumably in connection with task
                                                                                                   number 3 (extraction line optical design)
         Develop & prototype & beam test cavity BPM
  43                                                      Instrumentation Electronic Engineering   0.1 mm resolution - 5 10^(-5) precision
         for pre-IP energy spectrometer
         Develop & prototype & beam test large
  44                                                      Instrumentation Electronic Engineering
         aperture BPMs for BDS
  45     Laser wire prototypes & tests                    Instrumentation Experimental Physics
  46     Develop & prototype & beam test BPMs for IR      Instrumentation Experimental Physics
Task_ID                       Task                           Topic             Speciality                        Description
          Develop next generation nanometer scale
  47                                                     Instrumentation Experimental Physics
          beam size monitor
          Develop conceptual plan for post-IP energy
  48                                                     Instrumentation Experimental Physics   Specify magnets and detectors required
          spectrometer
                                                                                                Beam profile measurement with 4-5 mm
  49      Laser wire design, prototypes & tests          Instrumentation Experimental Physics
                                                                                                resolution
          SLC style wire scanner design, prototypes, &                                          Beam profile measurement with 4-5 mm
  50                                                     Instrumentation Experimental Physics
          test                                                                                  resolution
          Shintake laser interferometer design,
  51                                                     Instrumentation Experimental Physics
          prototypes & tests
          Conceptual design of Pre-IP and Post-IP
  52                                                     Instrumentation Experimental Physics
          compton polarimeters
          Design, prototypes & tests of a RF cavity to
                                                                                                Precision required ? - Precision achieved in
  53      provide time-dependent kick allowing to        Instrumentation RF Engineering
                                                                                                tests ?
          extract bunch length from transverse size
                                                                                                Most stringent precision requirement, of about
                                                                                                ~ 0.1 um, is from the upstream spectrometer -
  54      Beam position monitors based on cavity         Instrumentation RF Engineering         Elsewhere in the BDS requirements are ~
                                                                                                1um - To be tested in beam environment, with
                                                                                                high SR
                                                                                                In final doublet for beam-beam deflections -
          Beam position monitors based on stripline and
  55                                                    Instrumentation RF Engineering          Precision ~ 5 um ? - To be tested in beam
          on cavity
                                                                                                environment, with high SR

                                                          IP Collision
  56      Study of tuning techniques                                     Accelerator Physics
                                                          Optimization

          Study effect of S-shaped bunches on             IP Collision
  57                                                                     Accelerator Physics
          Luminosity stabilization                        Optimization
Task_ID                        Task                             Topic             Speciality                         Description
                                                                                                   Specify tolerances for vibration as function of
                                                                                                   frequency given baseline performance of
                                                                                                   bunch-bunch and train-train feedback and
          Study of integrated feedback system                IP Collision                          decide if any other vibration suppression or
  58                                                                        Accelerator Physics
          performance                                        Optimization                          feedback systems (support tube,
                                                                                                   FONT/FEATHER, inertial stabilization, optical
                                                                                                   anchor) are required to reduce risk that
                                                                                                   tolerances not met
          Feasibility study of RF cavity for angle           IP Collision
  59                                                                        Accelerator Physics
          feedback                                           Optimization
                                                             IP Collision                          Identify diagnostics for measuring and
  60      Luminosity diagnostic study                                       Accelerator Physics
                                                             Optimization                          optimizing beam parameters
                                                                                                   Fast + slow feedback to maintain optimal
                                                                                                   steering and optical tuning on the relevant
          Optimize LUM by using beam-beam                                                          time-scales - Trajectory feedback at IP with
                                                             IP Collision
  61      deflections, pairs and BDS trajectory                             Accelerator Physics    “realistic” beams has been simulated -
                                                             Optimization
          measuremnts                                                                              Extraction of steering misalignements and
                                                                                                   beam optical parameters using the LCAL has
                                                                                                   also been studied (see previous task)
          Experimental measurements of quad stability        IP Collision                          Urgently needed as design optimization of the
  62                                                                        Experimental Physics
          in linac cryostat                                  Optimization                          major linac component
          Experimental measurements of cold mass             IP Collision
  63                                                                        Experimental Physics
          stability in SC Final Quad                         Optimization
          Study utility/location of a Shintake style laser   IP Collision
  64                                                                        Experimental Physics
          interferometer                                     Optimization
                                                                                                   Beam parameter vs Observables as a
          Pair monitor performance study and                 IP Collision                          function of beam shape, crossing angle,
  65                                                                        HEP Simulation
          conceptual design                                  Optimization                          conceptual design of detector, algorithm
                                                                                                   (extension of A.Stahl analysis)
                                                                                                   Study tolerances and luminosity performance
  66      L* Study                                            IR Layout     Accelerator Physics
                                                                                                   as a function of L*
          Crab cavity prototype tests of phase control
  67                                                          IR Layout     Experimental Physics
          and stability
          Agree on working model (Strawman) for IR                                                 Suggest TESLA 0mrad model and NLC 20-
  68                                                          IR Layout     Experimental Physics
          Layout for both IRs                                                                      mrad models as strawmen
Task_ID                        Task                          Topic             Speciality                          Description
                                                                                                  These to include quad support with alignment
  69      Conceptual IR Engineering design                 IR Layout     Experimental Physics     and in situ adjustments; cable access;
                                                                                                  detector access; vacuum scheme, etc.

  70      Detailed IR Engineering design                   IR Layout     Mechanical Engineering
                                                                                                  These should be logically complete: 2 IRs,
  71      Agree on working BDIR model                        Optics      Accelerator Physics      FEXT lines, all Beam Dumps, Pre-IP E & Pol,
                                                                                                  post-IP E & Pol. if allowed
          Assemble and release internally consistent set
  72      of BDIR decks describing working BDIR              Optics      Accelerator Physics
          model
                                                                                                  Adequate bandwidth and optical properties
                                                                                                  appropriate for post-IP polarization and energy
  73      Extraction Line Design                             Optics      Accelerator Physics
                                                                                                  measurement; L*(ext) optimization; apertures;
                                                                                                  solenoid compensation if required

  74      Solenoid compensation study                        Optics      Accelerator Physics
          Study of impact of last drift space before
  75      detector required for zero or very small           Optics      Accelerator Physics
          crossing angle designs
  76      Design of final doublet or quadruplet              Optics      Accelerator Physics
                                                                                                  Decide between traditional optics or that with
  77      Study of final focus philosophy                    Optics      Accelerator Physics
                                                                                                  local correction
  78      Study of multi-TeV upgrade modifications           Optics      Accelerator Physics
  79      Study effect of wakefields in BDS                  Optics      Accelerator Physics
          Design of Optically matched spin rotators in
  80                                                         Optics      Accelerator Physics
          RTL sections
                                                                                                  Where do the dumps go? TESLA model; US
  81      Conceptual Beam Dump engineering design            Optics      Mechanical Engineering
                                                                                                  Options model?
  82      Impact of apertures on SUSY                      Simulations   Experimental Physics
Task_ID                       Task                            Topic             Speciality                        Description
          Estimate uncertainty in rate of incoherent pair
  83                                                        Simulations   Experimental Physics
          production and impact on VXD-Layer 1
                                                                                                 Understand precision, detector requirements
          Continue study of how shape of bhabha
                                                                                                 for reconstructing the average cms energy,
  84      energy distribution as measured in forward        Simulations   Experimental Physics
                                                                                                 the width of the core of the distribution and the
          calorimeters is measure of cms Energy
                                                                                                 event fraction in lower tail
          Continue study of how to infer CMS energy                                              Under study in several places - Statistics
  85      from measurements of radiative returns to the     Simulations   Experimental Physics   limited if only muons are used. Can ee, tt and
          Z [ee -> (Z -> ll,qq) g]                                                               qq be used ? Systematics evaluation
          Continue study of how to infer the event boost
          which results from the ISR and beamstrahlung
  86                                                        Simulations   Experimental Physics
          using measurements of the acollinearity in
          Bhabha events
          Define energy measurement scenario using
  87      the complementary information from beam           Simulations   Experimental Physics
          and physics measurements
                                                                                                 Design under study by collaboration led by
                                                                                                 DESY-Zeuthen - Energy resolution ~ 10 %
          Use LAT to measure Bhabha cross-section -                                              stochastic and ~ 1 % constant term - Specify
  88      Provide hermetic calorimetric coverage (83.8      Simulations   Experimental Physics   accuracy requirement for absolute
          to 27.5 mrad)                                                                          measurement (base-line HE machine versus
                                                                                                 GigaZ option) and study implications - Impact
                                                                                                 of a crossing angle
                                                                                                 Design under study by collaboration led by
                                                                                                 DESY-Zeuthen - Relative accuracy 1 % in 30-
                                                                                                 50 ns -> input to luminosity feedback loop -
          Use LCAL to measure pairs and track fast
                                                                                                 Optimise electron identification (and,
  89      luminosity changes - Provide hermetic             Simulations   Experimental Physics
                                                                                                 separately) veto capabilities in the presence of
          calorimetric coverage (30 to 5.4 mrad)
                                                                                                 pair and other radiation background from the
                                                                                                 beam-beam interaction - Impact of a crossing
                                                                                                 angle
Task_ID                       Task                       Topic             Speciality                         Description
                                                                                            Works without e+ polarisation - Absolute
                                                                                            precision wrt collected luminosity ? Early
          Continue analysis of ee -> WW and ee ->
  90                                                   Simulations   Experimental Physics   study by Klaus Mönig and later by François
          Wen processes for polarization information
                                                                                            Richard - Full analysis needed to get real
                                                                                            estimate on precision ?
          BeamCal performance study and conceptual                                          Electron ID in 5-30mrad forward calorimeter;
  91                                                   Simulations   HEP Simulation
          design                                                                            Improved e- ID algorithm
Begin      Due                 Contributors
                 with KEK, UK, SLAC, CERN
9/1/2005   TDR
                 participation

 Now       CDR   PEP-II, KEK-B, ATF, UK ???


 Now       TDR   LLNL


 Now       TDR   LLNL
 Now       TDR   SLAC
 Now       TDR   SLAC, UK

2 years    TDR


2 years    TDR

 CDR       TDR
 CDR       TDR
1 year     CDR


                 SLAC, FNAL, BNL, UK, Orsay, Saclay,
 Now       CDR
                 KEK
 Now       CDR   SLAC, BNL, UK, Orsay, Saclay, KEK
                 SLAC, FNAL, BNL, UK, Orsay, Saclay,
 Now       CDR
                 KEK
                 SLAC, FNAL, BNL, UK, Orsay, Saclay,
                 KEK


                 SLAC, FNAL, BNL, UK, Orsay, Saclay,
 Now       CDR
                 KEK
Begin   Due                Contributors
              SLAC, FNAL, BNL, UK, Orsay, Saclay,
Now     CDR
              KEK
              SLAC, FNAL, BNL, UK, Orsay, Saclay,
Now     CDR
              KEK



Now     CDR   SLAC, BNL, UK, Orsay, Saclay, KEK



              SLAC, FNAL, BNL, UK, Orsay, Saclay,
              KEK

Now     CDR   SLAC, BNL, UK, Orsay, Saclay, KEK


CDR     TDR   UK

              SLAC, FNAL, BNL, UK, Orsay, Saclay,
Now     CDR
              KEK
Now     TDR   SLAC, CERN

Now     TDR




Now     TDR   SLAC, UK

Now     CDR   SLAC, BNL, UK, Orsay, Saclay, KEK
Now     CDR   BNL
Now     CDR   BNL
Now     CDR   KEK, Kyoto
Begin   Due                Contributors
 Now    TDR   KEK, Kyoto
Now     CDR   Orsay, Saclay, DESY

Now     TDR   Orsay, Saclay, DESY

Now     CDR   LLNL

Now     CDR   LLNL

Now     TDR   LLNL

Now     TDR   LLNL

Now     TDR   LLNL




 ?      TDR   SLAC, DESY

 ?      TDR   SLAC, DESY
Now     TDR   KEK, UK
ASAP    TDR   SLAC, DESY
Begin    Due                  Contributors
        Commis
ATP             KEK
        sioning



               G. Blair




               P. Schüler




               J. Schreiber




Now      CDR   SLAC, BNL, UK, Orsay, Saclay, KEK


Now      CDR
Begin   Due               Contributors




Now     CDR




ASAP    CDR

Now     CDR




              G. White




ASAP    CDR   BNL

Now     TDR   BNL




Now     TDR


Now     CDR   SLAC, BNL, UK, Orsay, Saclay, KEK

Now     CDR   UK, FNAL?

Now     ASAP SLAC, BNL, UK, Orsay, Saclay, KEK
Begin   Due              Contributors


Now     CDR   SLAC, UK, DESY


CDR     TDR


Now     ASAP SLAC, BNL, UK, Orsay, Saclay, KEK


Now     CDR   SLAC, BNL, UK, Orsay, Saclay, KEK



Now     CDR   SLAC, BNL, UK, Orsay, Saclay, KEK



Now     CDR   SLAC, BNL, UK, Orsay, Saclay, KEK


Now     CDR   SLAC, BNL, UK, Orsay, Saclay, KEK


Now     CDR   SLAC, BNL, UK, Orsay, Saclay, KEK

Now     CDR   SLAC, BNL, UK, Orsay, Saclay, KEK

Now     CDR   SLAC, BNL, UK, Orsay, Saclay, KEK
Now     TDR



Now     CDR

Now     CDR   SLAC, BNL, UK, Orsay, Saclay, KEK
Begin   Due               Contributors




              D. Miller




              A. Stahl




              A. Stahl
Begin   Due   Contributors




Now     TDR
Choice_ID                         Choice
    1       Crossing Angle-(IR1/IR2)
    2       Final Doublet Technology (IR1/IR2)
    3       L* (IR1/IR2)
    4       Detector VXD inner radius (IR1/IR2)

   5        Collimation Choices (both Irs)

   6        MPS Questions



   7        Beam Stabilization issues



    8       Detector Questions
    9       Instrumentation Choices
   10       Risk Mitigation
                Choice_Description




Collimation material & shape, Passive or
Conumable, Order of betatron-energy collimation,
collimation before/after IP switch
#bunches allowed to hit collimator
Yes/No: Rely on fast feedback solely; Yes/No:
Additional active correction of FD; Yes/No: Additional
fast feedback at BDS entrance; Yes/No: Additional
fast feedbacks along the linac; Yes/No: Support tube
across IP
Impact of EMI, gamma-gamma implications

Beam Tests
Choice_ID                 Choice                 Task_ID
        1   Crossing Angle-(IR1/IR2)                2
        1   Crossing Angle-(IR1/IR2)                7
        1   Crossing Angle-(IR1/IR2)               18
        1   Crossing Angle-(IR1/IR2)               19
        1   Crossing Angle-(IR1/IR2)               20
        1   Crossing Angle-(IR1/IR2)               21
        1   Crossing Angle-(IR1/IR2)               22
        1   Crossing Angle-(IR1/IR2)               30
        1   Crossing Angle-(IR1/IR2)               31
        1   Crossing Angle-(IR1/IR2)               32
        1   Crossing Angle-(IR1/IR2)               33
        1   Crossing Angle-(IR1/IR2)               34
        1   Crossing Angle-(IR1/IR2)               35
        1   Crossing Angle-(IR1/IR2)               36
        1   Crossing Angle-(IR1/IR2)               42
        1   Crossing Angle-(IR1/IR2)               53
        1   Crossing Angle-(IR1/IR2)               66
        1   Crossing Angle-(IR1/IR2)               67
        1   Crossing Angle-(IR1/IR2)               68
        1   Crossing Angle-(IR1/IR2)               69
        1   Crossing Angle-(IR1/IR2)               70
        1   Crossing Angle-(IR1/IR2)               74
        1   Crossing Angle-(IR1/IR2)               75
        1   Crossing Angle-(IR1/IR2)               76
        1   Crossing Angle-(IR1/IR2)               81
        1   Crossing Angle-(IR1/IR2)               82
        2   Final Doublet Technology (IR1/IR2)      9
        2   Final Doublet Technology (IR1/IR2)     18
        2   Final Doublet Technology (IR1/IR2)     19
        2   Final Doublet Technology (IR1/IR2)     20
        2   Final Doublet Technology (IR1/IR2)     21
        2   Final Doublet Technology (IR1/IR2)     22
        2   Final Doublet Technology (IR1/IR2)     27
        2   Final Doublet Technology (IR1/IR2)     30
        2   Final Doublet Technology (IR1/IR2)     31
        2   Final Doublet Technology (IR1/IR2)     32
        2   Final Doublet Technology (IR1/IR2)     33
        2   Final Doublet Technology (IR1/IR2)     34
        2   Final Doublet Technology (IR1/IR2)     35
        2   Final Doublet Technology (IR1/IR2)     58
        2   Final Doublet Technology (IR1/IR2)     62
        2   Final Doublet Technology (IR1/IR2)     63
        2   Final Doublet Technology (IR1/IR2)     66
        2   Final Doublet Technology (IR1/IR2)     67
        2   Final Doublet Technology (IR1/IR2)     69
        2   Final Doublet Technology (IR1/IR2)     70
        2   Final Doublet Technology (IR1/IR2)     73
        2   Final Doublet Technology (IR1/IR2)     74
        2   Final Doublet Technology (IR1/IR2)     76
        2   Final Doublet Technology (IR1/IR2)     82
        3   L* (IR1/IR2)                            1
3   L* (IR1/IR2)    2
3   L* (IR1/IR2)    3
3   L* (IR1/IR2)    4
3   L* (IR1/IR2)    5
3   L* (IR1/IR2)    6
3   L* (IR1/IR2)    7
3   L* (IR1/IR2)    8
3   L* (IR1/IR2)    9
3   L* (IR1/IR2)   10
3   L* (IR1/IR2)   11
3   L* (IR1/IR2)   12
3   L* (IR1/IR2)   13
3   L* (IR1/IR2)   14
3   L* (IR1/IR2)   15
3   L* (IR1/IR2)   16
3   L* (IR1/IR2)   17
3   L* (IR1/IR2)   18
3   L* (IR1/IR2)   19
3   L* (IR1/IR2)   20
3   L* (IR1/IR2)   21
3   L* (IR1/IR2)   22
3   L* (IR1/IR2)   23
3   L* (IR1/IR2)   24
3   L* (IR1/IR2)   25
3   L* (IR1/IR2)   26
3   L* (IR1/IR2)   27
3   L* (IR1/IR2)   28
3   L* (IR1/IR2)   29
3   L* (IR1/IR2)   30
3   L* (IR1/IR2)   31
3   L* (IR1/IR2)   32
3   L* (IR1/IR2)   33
3   L* (IR1/IR2)   34
3   L* (IR1/IR2)   35
3   L* (IR1/IR2)   36
3   L* (IR1/IR2)   37
3   L* (IR1/IR2)   38
3   L* (IR1/IR2)   39
3   L* (IR1/IR2)   40
3   L* (IR1/IR2)   41
3   L* (IR1/IR2)   42
3   L* (IR1/IR2)   43
3   L* (IR1/IR2)   44
3   L* (IR1/IR2)   45
3   L* (IR1/IR2)   46
3   L* (IR1/IR2)   47
3   L* (IR1/IR2)   48
3   L* (IR1/IR2)   49
3   L* (IR1/IR2)   50
3   L* (IR1/IR2)   51
3   L* (IR1/IR2)   52
3   L* (IR1/IR2)   53
3   L* (IR1/IR2)                          54
3   L* (IR1/IR2)                          55
3   L* (IR1/IR2)                          56
3   L* (IR1/IR2)                          57
3   L* (IR1/IR2)                          58
3   L* (IR1/IR2)                          59
3   L* (IR1/IR2)                          60
3   L* (IR1/IR2)                          61
3   L* (IR1/IR2)                          62
3   L* (IR1/IR2)                          63
3   L* (IR1/IR2)                          64
3   L* (IR1/IR2)                          65
3   L* (IR1/IR2)                          66
3   L* (IR1/IR2)                          67
3   L* (IR1/IR2)                          68
3   L* (IR1/IR2)                          69
3   L* (IR1/IR2)                          70
3   L* (IR1/IR2)                          71
3   L* (IR1/IR2)                          72
3   L* (IR1/IR2)                          73
3   L* (IR1/IR2)                          74
3   L* (IR1/IR2)                          75
3   L* (IR1/IR2)                          76
3   L* (IR1/IR2)                          77
3   L* (IR1/IR2)                          78
3   L* (IR1/IR2)                          79
3   L* (IR1/IR2)                          80
3   L* (IR1/IR2)                          81
3   L* (IR1/IR2)                          82
3   L* (IR1/IR2)                          83
3   L* (IR1/IR2)                          84
3   L* (IR1/IR2)                          85
3   L* (IR1/IR2)                          86
3   L* (IR1/IR2)                          87
3   L* (IR1/IR2)                          88
3   L* (IR1/IR2)                          89
3   L* (IR1/IR2)                          90
3   L* (IR1/IR2)                          91
4   Detector VXD inner radius (IR1/IR2)    1
4   Detector VXD inner radius (IR1/IR2)    2
4   Detector VXD inner radius (IR1/IR2)    3
4   Detector VXD inner radius (IR1/IR2)    4
4   Detector VXD inner radius (IR1/IR2)    5
4   Detector VXD inner radius (IR1/IR2)    6
4   Detector VXD inner radius (IR1/IR2)    7
4   Detector VXD inner radius (IR1/IR2)    8
4   Detector VXD inner radius (IR1/IR2)    9
4   Detector VXD inner radius (IR1/IR2)   10
4   Detector VXD inner radius (IR1/IR2)   11
4   Detector VXD inner radius (IR1/IR2)   12
4   Detector VXD inner radius (IR1/IR2)   13
4   Detector VXD inner radius (IR1/IR2)   14
4   Detector VXD inner radius (IR1/IR2)   15
4   Detector VXD inner radius (IR1/IR2)   16
4   Detector VXD inner radius (IR1/IR2)   17
4   Detector VXD inner radius (IR1/IR2)   18
4   Detector VXD inner radius (IR1/IR2)   19
4   Detector VXD inner radius (IR1/IR2)   20
4   Detector VXD inner radius (IR1/IR2)   21
4   Detector VXD inner radius (IR1/IR2)   22
4   Detector VXD inner radius (IR1/IR2)   23
4   Detector VXD inner radius (IR1/IR2)   24
4   Detector VXD inner radius (IR1/IR2)   25
4   Detector VXD inner radius (IR1/IR2)   26
4   Detector VXD inner radius (IR1/IR2)   27
4   Detector VXD inner radius (IR1/IR2)   28
4   Detector VXD inner radius (IR1/IR2)   29
4   Detector VXD inner radius (IR1/IR2)   30
4   Detector VXD inner radius (IR1/IR2)   31
4   Detector VXD inner radius (IR1/IR2)   32
4   Detector VXD inner radius (IR1/IR2)   33
4   Detector VXD inner radius (IR1/IR2)   34
4   Detector VXD inner radius (IR1/IR2)   35
4   Detector VXD inner radius (IR1/IR2)   36
4   Detector VXD inner radius (IR1/IR2)   37
4   Detector VXD inner radius (IR1/IR2)   38
4   Detector VXD inner radius (IR1/IR2)   39
4   Detector VXD inner radius (IR1/IR2)   40
4   Detector VXD inner radius (IR1/IR2)   41
4   Detector VXD inner radius (IR1/IR2)   42
4   Detector VXD inner radius (IR1/IR2)   43
4   Detector VXD inner radius (IR1/IR2)   44
4   Detector VXD inner radius (IR1/IR2)   45
4   Detector VXD inner radius (IR1/IR2)   46
4   Detector VXD inner radius (IR1/IR2)   47
4   Detector VXD inner radius (IR1/IR2)   48
4   Detector VXD inner radius (IR1/IR2)   49
4   Detector VXD inner radius (IR1/IR2)   50
4   Detector VXD inner radius (IR1/IR2)   51
4   Detector VXD inner radius (IR1/IR2)   52
4   Detector VXD inner radius (IR1/IR2)   53
4   Detector VXD inner radius (IR1/IR2)   54
4   Detector VXD inner radius (IR1/IR2)   55
4   Detector VXD inner radius (IR1/IR2)   56
4   Detector VXD inner radius (IR1/IR2)   57
4   Detector VXD inner radius (IR1/IR2)   58
4   Detector VXD inner radius (IR1/IR2)   59
4   Detector VXD inner radius (IR1/IR2)   60
4   Detector VXD inner radius (IR1/IR2)   61
4   Detector VXD inner radius (IR1/IR2)   62
4   Detector VXD inner radius (IR1/IR2)   63
4   Detector VXD inner radius (IR1/IR2)   64
4   Detector VXD inner radius (IR1/IR2)   65
4   Detector VXD inner radius (IR1/IR2)   66
4   Detector VXD inner radius (IR1/IR2)   67
4   Detector VXD inner radius (IR1/IR2)   68
4   Detector VXD inner radius (IR1/IR2)   69
4   Detector VXD inner radius (IR1/IR2)   70
4   Detector VXD inner radius (IR1/IR2)   71
4   Detector VXD inner radius (IR1/IR2)   72
4   Detector VXD inner radius (IR1/IR2)   73
4   Detector VXD inner radius (IR1/IR2)   74
4   Detector VXD inner radius (IR1/IR2)   75
4   Detector VXD inner radius (IR1/IR2)   76
4   Detector VXD inner radius (IR1/IR2)   77
4   Detector VXD inner radius (IR1/IR2)   78
4   Detector VXD inner radius (IR1/IR2)   79
4   Detector VXD inner radius (IR1/IR2)   80
4   Detector VXD inner radius (IR1/IR2)   81
4   Detector VXD inner radius (IR1/IR2)   82
4   Detector VXD inner radius (IR1/IR2)   83
4   Detector VXD inner radius (IR1/IR2)   84
4   Detector VXD inner radius (IR1/IR2)   85
4   Detector VXD inner radius (IR1/IR2)   86
4   Detector VXD inner radius (IR1/IR2)   87
4   Detector VXD inner radius (IR1/IR2)   88
4   Detector VXD inner radius (IR1/IR2)   89
4   Detector VXD inner radius (IR1/IR2)   90
4   Detector VXD inner radius (IR1/IR2)   91
5   Collimation Choices (both Irs)         1
5   Collimation Choices (both Irs)         2
5   Collimation Choices (both Irs)         3
5   Collimation Choices (both Irs)         4
5   Collimation Choices (both Irs)         5
5   Collimation Choices (both Irs)         6
5   Collimation Choices (both Irs)         7
5   Collimation Choices (both Irs)         8
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5   Collimation Choices (both Irs)        11
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5   Collimation Choices (both Irs)        13
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5   Collimation Choices (both Irs)        15
5   Collimation Choices (both Irs)        16
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5   Collimation Choices (both Irs)        19
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5   Collimation Choices (both Irs)        21
5   Collimation Choices (both Irs)        22
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5   Collimation Choices (both Irs)        24
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5   Collimation Choices (both Irs)        26
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5   Collimation Choices (both Irs)   62
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5   Collimation Choices (both Irs)   65
5   Collimation Choices (both Irs)   66
5   Collimation Choices (both Irs)   67
5   Collimation Choices (both Irs)   68
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5   Collimation Choices (both Irs)   70
5   Collimation Choices (both Irs)   71
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5   Collimation Choices (both Irs)   73
5   Collimation Choices (both Irs)   74
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5   Collimation Choices (both Irs)   76
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5   Collimation Choices (both Irs)   78
5   Collimation Choices (both Irs)   79
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5   Collimation Choices (both Irs)   82
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5   Collimation Choices (both Irs)   84
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5   Collimation Choices (both Irs)   86
5   Collimation Choices (both Irs)   87
5   Collimation Choices (both Irs)   88
5   Collimation Choices (both Irs)   89
5   Collimation Choices (both Irs)   90
5   Collimation Choices (both Irs)   91
6   MPS Questions                     1
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6   MPS Questions               91
7   Beam Stabilization issues    1
7   Beam Stabilization issues    2
7   Beam Stabilization issues    3
7   Beam Stabilization issues    4
7   Beam Stabilization issues    5
7   Beam Stabilization issues    6
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7   Beam Stabilization issues   89
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7   Beam Stabilization issues   91
8   Detector Questions           1
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8   Detector Questions        88
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8   Detector Questions        90
8   Detector Questions        91
9   Instrumentation Choices    1
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9   Instrumentation Choices    3
9   Instrumentation Choices    4
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10   Risk Mitigation            1
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                                                        Task
Electrostatic separator experimental tests in harsh environment, up to 500 GeV/beam, feasibility and reliability
BPM tests in IR-like environment
Study backgrounds caused by main beam and halo as a function of crossing angle and extraction scheme
Septum damage and background studies
Detector background analyses: Core Beam, Halo & SR
Recalculation of all detector backgrounds once CDR version of IR Layouts are finalized
Study of engineering layouts and conflicts
Engineering study of compact SC quad
Prototype of compact SC quad
Engineering study of compact PM quad
Prototype of compact PM quad
Engineering study of large aperture traditional SC quad
Prototype of large aperture traditional SC quad
Study of gamma-gamma backgrounds vs. crossing angle
Track relative changes in energy distribution by measuring the spent beam
Design, prototypes & tests of a RF cavity to provide time-dependent kick allowing to extract bunch length from transverse size
L* Study
Crab cavity prototype tests of phase control and stability
Agree on working model (Strawman) for IR Layout for both IRs
Conceptual IR Engineering design
Detailed IR Engineering design
Solenoid compensation study
Study of impact of last drift space before detector required for zero or very small crossing angle designs
Design of final doublet or quadruplet
Conceptual Beam Dump engineering design
Impact of apertures on SUSY
Prototype IR in ESA
Study backgrounds caused by main beam and halo as a function of crossing angle and extraction scheme
Septum damage and background studies
Detector background analyses: Core Beam, Halo & SR
Recalculation of all detector backgrounds once CDR version of IR Layouts are finalized
Study of engineering layouts and conflicts
Engineering study/prototypes any auxiliary vibration suppression system that can substantially reduce risk due to relative vibrati
Engineering study of compact SC quad
Prototype of compact SC quad
Engineering study of compact PM quad
Prototype of compact PM quad
Engineering study of large aperture traditional SC quad
Prototype of large aperture traditional SC quad
Study of integrated feedback system performance
Experimental measurements of quad stability in linac cryostat
Experimental measurements of cold mass stability in SC Final Quad
L* Study
Crab cavity prototype tests of phase control and stability
Conceptual IR Engineering design
Detailed IR Engineering design
Extraction Line Design
Solenoid compensation study
Design of final doublet or quadruplet
Impact of apertures on SUSY
Experimental tests of compact optics
Electrostatic separator experimental tests in harsh environment, up to 500 GeV/beam, feasibility and reliability
Experimental verification of backscattered photons in multi-bunch accelerator environment
Experimental verification of photon-photon collisions
Collimator material damage tests
Collimator wakefield tests
BPM tests in IR-like environment
Pair monitor prototype beam test in ESA
Prototype IR in ESA
BPM tests at ESA and ATF
Develop “disrupted” and “pairs” beam capability at ESA
EMI Test of VXD and Detector electronics
Collimation Study
Tail-folding study
Collimation system performance study
Re-estimate of beam halo and decision on halo/beam fraction collimation system and shielding will be designed to handle
Muon backgrounds
Study backgrounds caused by main beam and halo as a function of crossing angle and extraction scheme
Septum damage and background studies
Detector background analyses: Core Beam, Halo & SR
Recalculation of all detector backgrounds once CDR version of IR Layouts are finalized
Study of engineering layouts and conflicts
Develop & prototype Interferometric network for specific areas (e.g. energy spectrometer)
Collimator material damage analysis
Prototype collimators-exotic
Prototype collimators-traditional
Engineering study/prototypes any auxiliary vibration suppression system that can substantially reduce risk due to relative vibrati
Engineering design & prototype BDS (not IR) quad supports and movers
Document lengths, part counts, power requirements for working BDIR model
Engineering study of compact SC quad
Prototype of compact SC quad
Engineering study of compact PM quad
Prototype of compact PM quad
Engineering study of large aperture traditional SC quad
Prototype of large aperture traditional SC quad
Study of gamma-gamma backgrounds vs. crossing angle
Mechanical design of optical cavity for g-g laser
Experimental test of g-g drive laser
Experimental test of g-g mirror stability, damage
Experimental test of g-g optical cavity
Measurement of spin precession through existing bending magnets to extract the integrated bending field used is a spectromet
Track relative changes in energy distribution by measuring the spent beam
Develop & prototype & beam test cavity BPM for pre-IP energy spectrometer
Develop & prototype & beam test large aperture BPMs for BDS
Laser wire prototypes & tests
Develop & prototype & beam test BPMs for IR
Develop next generation nanometer scale beam size monitor
Develop conceptual plan for post-IP energy spectrometer
Laser wire design, prototypes & tests
SLC style wire scanner design, prototypes, & test
Shintake laser interferometer design, prototypes & tests
Conceptual design of Pre-IP and Post-IP compton polarimeters
Design, prototypes & tests of a RF cavity to provide time-dependent kick allowing to extract bunch length from transverse size
Beam position monitors based on cavity
Beam position monitors based on stripline and on cavity
Study of tuning techniques
Study effect of S-shaped bunches on Luminosity stabilization
Study of integrated feedback system performance
Feasibility study of RF cavity for angle feedback
Luminosity diagnostic study
Optimize LUM by using beam-beam deflections, pairs and BDS trajectory measuremnts
Experimental measurements of quad stability in linac cryostat
Experimental measurements of cold mass stability in SC Final Quad
Study utility/location of a Shintake style laser interferometer
Pair monitor performance study and conceptual design
L* Study
Crab cavity prototype tests of phase control and stability
Agree on working model (Strawman) for IR Layout for both IRs
Conceptual IR Engineering design
Detailed IR Engineering design
Agree on working BDIR model
Assemble and release internally consistent set of BDIR decks describing working BDIR model
Extraction Line Design
Solenoid compensation study
Study of impact of last drift space before detector required for zero or very small crossing angle designs
Design of final doublet or quadruplet
Study of final focus philosophy
Study of multi-TeV upgrade modifications
Study effect of wakefields in BDS
Design of Optically matched spin rotators in RTL sections
Conceptual Beam Dump engineering design
Impact of apertures on SUSY
Estimate uncertainty in rate of incoherent pair production and impact on VXD-Layer 1
Continue study of how shape of bhabha energy distribution as measured in forward calorimeters is measure of cms Energy
Continue study of how to infer CMS energy from measurements of radiative returns to the Z [ee -> (Z -> ll,qq) g]
Continue study of how to infer the event boost which results from the ISR and beamstrahlung using measurements of the acolli
Define energy measurement scenario using the complementary information from beam and physics measurements
Use LAT to measure Bhabha cross-section - Provide hermetic calorimetric coverage (83.8 to 27.5 mrad)
Use LCAL to measure pairs and track fast luminosity changes - Provide hermetic calorimetric coverage (30 to 5.4 mrad)
Continue analysis of ee -> WW and ee -> Wen processes for polarization information
BeamCal performance study and conceptual design
Experimental tests of compact optics
Electrostatic separator experimental tests in harsh environment, up to 500 GeV/beam, feasibility and reliability
Experimental verification of backscattered photons in multi-bunch accelerator environment
Experimental verification of photon-photon collisions
Collimator material damage tests
Collimator wakefield tests
BPM tests in IR-like environment
Pair monitor prototype beam test in ESA
Prototype IR in ESA
BPM tests at ESA and ATF
Develop “disrupted” and “pairs” beam capability at ESA
EMI Test of VXD and Detector electronics
Collimation Study
Tail-folding study
Collimation system performance study
Re-estimate of beam halo and decision on halo/beam fraction collimation system and shielding will be designed to handle
Muon backgrounds
Study backgrounds caused by main beam and halo as a function of crossing angle and extraction scheme
Septum damage and background studies
Detector background analyses: Core Beam, Halo & SR
Recalculation of all detector backgrounds once CDR version of IR Layouts are finalized
Study of engineering layouts and conflicts
Develop & prototype Interferometric network for specific areas (e.g. energy spectrometer)
Collimator material damage analysis
Prototype collimators-exotic
Prototype collimators-traditional
Engineering study/prototypes any auxiliary vibration suppression system that can substantially reduce risk due to relative vibrati
Engineering design & prototype BDS (not IR) quad supports and movers
Document lengths, part counts, power requirements for working BDIR model
Engineering study of compact SC quad
Prototype of compact SC quad
Engineering study of compact PM quad
Prototype of compact PM quad
Engineering study of large aperture traditional SC quad
Prototype of large aperture traditional SC quad
Study of gamma-gamma backgrounds vs. crossing angle
Mechanical design of optical cavity for g-g laser
Experimental test of g-g drive laser
Experimental test of g-g mirror stability, damage
Experimental test of g-g optical cavity
Measurement of spin precession through existing bending magnets to extract the integrated bending field used is a spectromet
Track relative changes in energy distribution by measuring the spent beam
Develop & prototype & beam test cavity BPM for pre-IP energy spectrometer
Develop & prototype & beam test large aperture BPMs for BDS
Laser wire prototypes & tests
Develop & prototype & beam test BPMs for IR
Develop next generation nanometer scale beam size monitor
Develop conceptual plan for post-IP energy spectrometer
Laser wire design, prototypes & tests
SLC style wire scanner design, prototypes, & test
Shintake laser interferometer design, prototypes & tests
Conceptual design of Pre-IP and Post-IP compton polarimeters
Design, prototypes & tests of a RF cavity to provide time-dependent kick allowing to extract bunch length from transverse size
Beam position monitors based on cavity
Beam position monitors based on stripline and on cavity
Study of tuning techniques
Study effect of S-shaped bunches on Luminosity stabilization
Study of integrated feedback system performance
Feasibility study of RF cavity for angle feedback
Luminosity diagnostic study
Optimize LUM by using beam-beam deflections, pairs and BDS trajectory measuremnts
Experimental measurements of quad stability in linac cryostat
Experimental measurements of cold mass stability in SC Final Quad
Study utility/location of a Shintake style laser interferometer
Pair monitor performance study and conceptual design
L* Study
Crab cavity prototype tests of phase control and stability
Agree on working model (Strawman) for IR Layout for both IRs
Conceptual IR Engineering design
Detailed IR Engineering design
Agree on working BDIR model
Assemble and release internally consistent set of BDIR decks describing working BDIR model
Extraction Line Design
Solenoid compensation study
Study of impact of last drift space before detector required for zero or very small crossing angle designs
Design of final doublet or quadruplet
Study of final focus philosophy
Study of multi-TeV upgrade modifications
Study effect of wakefields in BDS
Design of Optically matched spin rotators in RTL sections
Conceptual Beam Dump engineering design
Impact of apertures on SUSY
Estimate uncertainty in rate of incoherent pair production and impact on VXD-Layer 1
Continue study of how shape of bhabha energy distribution as measured in forward calorimeters is measure of cms Energy
Continue study of how to infer CMS energy from measurements of radiative returns to the Z [ee -> (Z -> ll,qq) g]
Continue study of how to infer the event boost which results from the ISR and beamstrahlung using measurements of the acolli
Define energy measurement scenario using the complementary information from beam and physics measurements
Use LAT to measure Bhabha cross-section - Provide hermetic calorimetric coverage (83.8 to 27.5 mrad)
Use LCAL to measure pairs and track fast luminosity changes - Provide hermetic calorimetric coverage (30 to 5.4 mrad)
Continue analysis of ee -> WW and ee -> Wen processes for polarization information
BeamCal performance study and conceptual design
Experimental tests of compact optics
Electrostatic separator experimental tests in harsh environment, up to 500 GeV/beam, feasibility and reliability
Experimental verification of backscattered photons in multi-bunch accelerator environment
Experimental verification of photon-photon collisions
Collimator material damage tests
Collimator wakefield tests
BPM tests in IR-like environment
Pair monitor prototype beam test in ESA
Prototype IR in ESA
BPM tests at ESA and ATF
Develop “disrupted” and “pairs” beam capability at ESA
EMI Test of VXD and Detector electronics
Collimation Study
Tail-folding study
Collimation system performance study
Re-estimate of beam halo and decision on halo/beam fraction collimation system and shielding will be designed to handle
Muon backgrounds
Study backgrounds caused by main beam and halo as a function of crossing angle and extraction scheme
Septum damage and background studies
Detector background analyses: Core Beam, Halo & SR
Recalculation of all detector backgrounds once CDR version of IR Layouts are finalized
Study of engineering layouts and conflicts
Develop & prototype Interferometric network for specific areas (e.g. energy spectrometer)
Collimator material damage analysis
Prototype collimators-exotic
Prototype collimators-traditional
Engineering study/prototypes any auxiliary vibration suppression system that can substantially reduce risk due to relative vibrati
Engineering design & prototype BDS (not IR) quad supports and movers
Document lengths, part counts, power requirements for working BDIR model
Engineering study of compact SC quad
Prototype of compact SC quad
Engineering study of compact PM quad
Prototype of compact PM quad
Engineering study of large aperture traditional SC quad
Prototype of large aperture traditional SC quad
Study of gamma-gamma backgrounds vs. crossing angle
Mechanical design of optical cavity for g-g laser
Experimental test of g-g drive laser
Experimental test of g-g mirror stability, damage
Experimental test of g-g optical cavity
Measurement of spin precession through existing bending magnets to extract the integrated bending field used is a spectromet
Track relative changes in energy distribution by measuring the spent beam
Develop & prototype & beam test cavity BPM for pre-IP energy spectrometer
Develop & prototype & beam test large aperture BPMs for BDS
Laser wire prototypes & tests
Develop & prototype & beam test BPMs for IR
Develop next generation nanometer scale beam size monitor
Develop conceptual plan for post-IP energy spectrometer
Laser wire design, prototypes & tests
SLC style wire scanner design, prototypes, & test
Shintake laser interferometer design, prototypes & tests
Conceptual design of Pre-IP and Post-IP compton polarimeters
Design, prototypes & tests of a RF cavity to provide time-dependent kick allowing to extract bunch length from transverse size
Beam position monitors based on cavity
Beam position monitors based on stripline and on cavity
Study of tuning techniques
Study effect of S-shaped bunches on Luminosity stabilization
Study of integrated feedback system performance
Feasibility study of RF cavity for angle feedback
Luminosity diagnostic study
Optimize LUM by using beam-beam deflections, pairs and BDS trajectory measuremnts
Experimental measurements of quad stability in linac cryostat
Experimental measurements of cold mass stability in SC Final Quad
Study utility/location of a Shintake style laser interferometer
Pair monitor performance study and conceptual design
L* Study
Crab cavity prototype tests of phase control and stability
Agree on working model (Strawman) for IR Layout for both IRs
Conceptual IR Engineering design
Detailed IR Engineering design
Agree on working BDIR model
Assemble and release internally consistent set of BDIR decks describing working BDIR model
Extraction Line Design
Solenoid compensation study
Study of impact of last drift space before detector required for zero or very small crossing angle designs
Design of final doublet or quadruplet
Study of final focus philosophy
Study of multi-TeV upgrade modifications
Study effect of wakefields in BDS
Design of Optically matched spin rotators in RTL sections
Conceptual Beam Dump engineering design
Impact of apertures on SUSY
Estimate uncertainty in rate of incoherent pair production and impact on VXD-Layer 1
Continue study of how shape of bhabha energy distribution as measured in forward calorimeters is measure of cms Energy
Continue study of how to infer CMS energy from measurements of radiative returns to the Z [ee -> (Z -> ll,qq) g]
Continue study of how to infer the event boost which results from the ISR and beamstrahlung using measurements of the acolli
Define energy measurement scenario using the complementary information from beam and physics measurements
Use LAT to measure Bhabha cross-section - Provide hermetic calorimetric coverage (83.8 to 27.5 mrad)
Use LCAL to measure pairs and track fast luminosity changes - Provide hermetic calorimetric coverage (30 to 5.4 mrad)
Continue analysis of ee -> WW and ee -> Wen processes for polarization information
BeamCal performance study and conceptual design
Experimental tests of compact optics
Electrostatic separator experimental tests in harsh environment, up to 500 GeV/beam, feasibility and reliability
Experimental verification of backscattered photons in multi-bunch accelerator environment
Experimental verification of photon-photon collisions
Collimator material damage tests
Collimator wakefield tests
BPM tests in IR-like environment
Pair monitor prototype beam test in ESA
Prototype IR in ESA
BPM tests at ESA and ATF
Develop “disrupted” and “pairs” beam capability at ESA
EMI Test of VXD and Detector electronics
Collimation Study
Tail-folding study
Collimation system performance study
Re-estimate of beam halo and decision on halo/beam fraction collimation system and shielding will be designed to handle
Muon backgrounds
Study backgrounds caused by main beam and halo as a function of crossing angle and extraction scheme
Septum damage and background studies
Detector background analyses: Core Beam, Halo & SR
Recalculation of all detector backgrounds once CDR version of IR Layouts are finalized
Study of engineering layouts and conflicts
Develop & prototype Interferometric network for specific areas (e.g. energy spectrometer)
Collimator material damage analysis
Prototype collimators-exotic
Prototype collimators-traditional
Engineering study/prototypes any auxiliary vibration suppression system that can substantially reduce risk due to relative vibrati
Engineering design & prototype BDS (not IR) quad supports and movers
Document lengths, part counts, power requirements for working BDIR model
Engineering study of compact SC quad
Prototype of compact SC quad
Engineering study of compact PM quad
Prototype of compact PM quad
Engineering study of large aperture traditional SC quad
Prototype of large aperture traditional SC quad
Study of gamma-gamma backgrounds vs. crossing angle
Mechanical design of optical cavity for g-g laser
Experimental test of g-g drive laser
Experimental test of g-g mirror stability, damage
Experimental test of g-g optical cavity
Measurement of spin precession through existing bending magnets to extract the integrated bending field used is a spectromet
Track relative changes in energy distribution by measuring the spent beam
Develop & prototype & beam test cavity BPM for pre-IP energy spectrometer
Develop & prototype & beam test large aperture BPMs for BDS
Laser wire prototypes & tests
Develop & prototype & beam test BPMs for IR
Develop next generation nanometer scale beam size monitor
Develop conceptual plan for post-IP energy spectrometer
Laser wire design, prototypes & tests
SLC style wire scanner design, prototypes, & test
Shintake laser interferometer design, prototypes & tests
Conceptual design of Pre-IP and Post-IP compton polarimeters
Design, prototypes & tests of a RF cavity to provide time-dependent kick allowing to extract bunch length from transverse size
Beam position monitors based on cavity
Beam position monitors based on stripline and on cavity
Study of tuning techniques
Study effect of S-shaped bunches on Luminosity stabilization
Study of integrated feedback system performance
Feasibility study of RF cavity for angle feedback
Luminosity diagnostic study
Optimize LUM by using beam-beam deflections, pairs and BDS trajectory measuremnts
Experimental measurements of quad stability in linac cryostat
Experimental measurements of cold mass stability in SC Final Quad
Study utility/location of a Shintake style laser interferometer
Pair monitor performance study and conceptual design
L* Study
Crab cavity prototype tests of phase control and stability
Agree on working model (Strawman) for IR Layout for both IRs
Conceptual IR Engineering design
Detailed IR Engineering design
Agree on working BDIR model
Assemble and release internally consistent set of BDIR decks describing working BDIR model
Extraction Line Design
Solenoid compensation study
Study of impact of last drift space before detector required for zero or very small crossing angle designs
Design of final doublet or quadruplet
Study of final focus philosophy
Study of multi-TeV upgrade modifications
Study effect of wakefields in BDS
Design of Optically matched spin rotators in RTL sections
Conceptual Beam Dump engineering design
Impact of apertures on SUSY
Estimate uncertainty in rate of incoherent pair production and impact on VXD-Layer 1
Continue study of how shape of bhabha energy distribution as measured in forward calorimeters is measure of cms Energy
Continue study of how to infer CMS energy from measurements of radiative returns to the Z [ee -> (Z -> ll,qq) g]
Continue study of how to infer the event boost which results from the ISR and beamstrahlung using measurements of the acolli
Define energy measurement scenario using the complementary information from beam and physics measurements
Use LAT to measure Bhabha cross-section - Provide hermetic calorimetric coverage (83.8 to 27.5 mrad)
Use LCAL to measure pairs and track fast luminosity changes - Provide hermetic calorimetric coverage (30 to 5.4 mrad)
Continue analysis of ee -> WW and ee -> Wen processes for polarization information
BeamCal performance study and conceptual design
Experimental tests of compact optics
Electrostatic separator experimental tests in harsh environment, up to 500 GeV/beam, feasibility and reliability
Experimental verification of backscattered photons in multi-bunch accelerator environment
Experimental verification of photon-photon collisions
Collimator material damage tests
Collimator wakefield tests
BPM tests in IR-like environment
Pair monitor prototype beam test in ESA
Prototype IR in ESA
BPM tests at ESA and ATF
Develop “disrupted” and “pairs” beam capability at ESA
EMI Test of VXD and Detector electronics
Collimation Study
Tail-folding study
Collimation system performance study
Re-estimate of beam halo and decision on halo/beam fraction collimation system and shielding will be designed to handle
Muon backgrounds
Study backgrounds caused by main beam and halo as a function of crossing angle and extraction scheme
Septum damage and background studies
Detector background analyses: Core Beam, Halo & SR
Recalculation of all detector backgrounds once CDR version of IR Layouts are finalized
Study of engineering layouts and conflicts
Develop & prototype Interferometric network for specific areas (e.g. energy spectrometer)
Collimator material damage analysis
Prototype collimators-exotic
Prototype collimators-traditional
Engineering study/prototypes any auxiliary vibration suppression system that can substantially reduce risk due to relative vibrati
Engineering design & prototype BDS (not IR) quad supports and movers
Document lengths, part counts, power requirements for working BDIR model
Engineering study of compact SC quad
Prototype of compact SC quad
Engineering study of compact PM quad
Prototype of compact PM quad
Engineering study of large aperture traditional SC quad
Prototype of large aperture traditional SC quad
Study of gamma-gamma backgrounds vs. crossing angle
Mechanical design of optical cavity for g-g laser
Experimental test of g-g drive laser
Experimental test of g-g mirror stability, damage
Experimental test of g-g optical cavity
Measurement of spin precession through existing bending magnets to extract the integrated bending field used is a spectromet
Track relative changes in energy distribution by measuring the spent beam
Develop & prototype & beam test cavity BPM for pre-IP energy spectrometer
Develop & prototype & beam test large aperture BPMs for BDS
Laser wire prototypes & tests
Develop & prototype & beam test BPMs for IR
Develop next generation nanometer scale beam size monitor
Develop conceptual plan for post-IP energy spectrometer
Laser wire design, prototypes & tests
SLC style wire scanner design, prototypes, & test
Shintake laser interferometer design, prototypes & tests
Conceptual design of Pre-IP and Post-IP compton polarimeters
Design, prototypes & tests of a RF cavity to provide time-dependent kick allowing to extract bunch length from transverse size
Beam position monitors based on cavity
Beam position monitors based on stripline and on cavity
Study of tuning techniques
Study effect of S-shaped bunches on Luminosity stabilization
Study of integrated feedback system performance
Feasibility study of RF cavity for angle feedback
Luminosity diagnostic study
Optimize LUM by using beam-beam deflections, pairs and BDS trajectory measuremnts
Experimental measurements of quad stability in linac cryostat
Experimental measurements of cold mass stability in SC Final Quad
Study utility/location of a Shintake style laser interferometer
Pair monitor performance study and conceptual design
L* Study
Crab cavity prototype tests of phase control and stability
Agree on working model (Strawman) for IR Layout for both IRs
Conceptual IR Engineering design
Detailed IR Engineering design
Agree on working BDIR model
Assemble and release internally consistent set of BDIR decks describing working BDIR model
Extraction Line Design
Solenoid compensation study
Study of impact of last drift space before detector required for zero or very small crossing angle designs
Design of final doublet or quadruplet
Study of final focus philosophy
Study of multi-TeV upgrade modifications
Study effect of wakefields in BDS
Design of Optically matched spin rotators in RTL sections
Conceptual Beam Dump engineering design
Impact of apertures on SUSY
Estimate uncertainty in rate of incoherent pair production and impact on VXD-Layer 1
Continue study of how shape of bhabha energy distribution as measured in forward calorimeters is measure of cms Energy
Continue study of how to infer CMS energy from measurements of radiative returns to the Z [ee -> (Z -> ll,qq) g]
Continue study of how to infer the event boost which results from the ISR and beamstrahlung using measurements of the acolli
Define energy measurement scenario using the complementary information from beam and physics measurements
Use LAT to measure Bhabha cross-section - Provide hermetic calorimetric coverage (83.8 to 27.5 mrad)
Use LCAL to measure pairs and track fast luminosity changes - Provide hermetic calorimetric coverage (30 to 5.4 mrad)
Continue analysis of ee -> WW and ee -> Wen processes for polarization information
BeamCal performance study and conceptual design
Experimental tests of compact optics
Electrostatic separator experimental tests in harsh environment, up to 500 GeV/beam, feasibility and reliability
Experimental verification of backscattered photons in multi-bunch accelerator environment
Experimental verification of photon-photon collisions
Collimator material damage tests
Collimator wakefield tests
BPM tests in IR-like environment
Pair monitor prototype beam test in ESA
Prototype IR in ESA
BPM tests at ESA and ATF
Develop “disrupted” and “pairs” beam capability at ESA
EMI Test of VXD and Detector electronics
Collimation Study
Tail-folding study
Collimation system performance study
Re-estimate of beam halo and decision on halo/beam fraction collimation system and shielding will be designed to handle
Muon backgrounds
Study backgrounds caused by main beam and halo as a function of crossing angle and extraction scheme
Septum damage and background studies
Detector background analyses: Core Beam, Halo & SR
Recalculation of all detector backgrounds once CDR version of IR Layouts are finalized
Study of engineering layouts and conflicts
Develop & prototype Interferometric network for specific areas (e.g. energy spectrometer)
Collimator material damage analysis
Prototype collimators-exotic
Prototype collimators-traditional
Engineering study/prototypes any auxiliary vibration suppression system that can substantially reduce risk due to relative vibrati
Engineering design & prototype BDS (not IR) quad supports and movers
Document lengths, part counts, power requirements for working BDIR model
Engineering study of compact SC quad
Prototype of compact SC quad
Engineering study of compact PM quad
Prototype of compact PM quad
Engineering study of large aperture traditional SC quad
Prototype of large aperture traditional SC quad
Study of gamma-gamma backgrounds vs. crossing angle
Mechanical design of optical cavity for g-g laser
Experimental test of g-g drive laser
Experimental test of g-g mirror stability, damage
Experimental test of g-g optical cavity
Measurement of spin precession through existing bending magnets to extract the integrated bending field used is a spectromet
Track relative changes in energy distribution by measuring the spent beam
Develop & prototype & beam test cavity BPM for pre-IP energy spectrometer
Develop & prototype & beam test large aperture BPMs for BDS
Laser wire prototypes & tests
Develop & prototype & beam test BPMs for IR
Develop next generation nanometer scale beam size monitor
Develop conceptual plan for post-IP energy spectrometer
Laser wire design, prototypes & tests
SLC style wire scanner design, prototypes, & test
Shintake laser interferometer design, prototypes & tests
Conceptual design of Pre-IP and Post-IP compton polarimeters
Design, prototypes & tests of a RF cavity to provide time-dependent kick allowing to extract bunch length from transverse size
Beam position monitors based on cavity
Beam position monitors based on stripline and on cavity
Study of tuning techniques
Study effect of S-shaped bunches on Luminosity stabilization
Study of integrated feedback system performance
Feasibility study of RF cavity for angle feedback
Luminosity diagnostic study
Optimize LUM by using beam-beam deflections, pairs and BDS trajectory measuremnts
Experimental measurements of quad stability in linac cryostat
Experimental measurements of cold mass stability in SC Final Quad
Study utility/location of a Shintake style laser interferometer
Pair monitor performance study and conceptual design
L* Study
Crab cavity prototype tests of phase control and stability
Agree on working model (Strawman) for IR Layout for both IRs
Conceptual IR Engineering design
Detailed IR Engineering design
Agree on working BDIR model
Assemble and release internally consistent set of BDIR decks describing working BDIR model
Extraction Line Design
Solenoid compensation study
Study of impact of last drift space before detector required for zero or very small crossing angle designs
Design of final doublet or quadruplet
Study of final focus philosophy
Study of multi-TeV upgrade modifications
Study effect of wakefields in BDS
Design of Optically matched spin rotators in RTL sections
Conceptual Beam Dump engineering design
Impact of apertures on SUSY
Estimate uncertainty in rate of incoherent pair production and impact on VXD-Layer 1
Continue study of how shape of bhabha energy distribution as measured in forward calorimeters is measure of cms Energy
Continue study of how to infer CMS energy from measurements of radiative returns to the Z [ee -> (Z -> ll,qq) g]
Continue study of how to infer the event boost which results from the ISR and beamstrahlung using measurements of the acolli
Define energy measurement scenario using the complementary information from beam and physics measurements
Use LAT to measure Bhabha cross-section - Provide hermetic calorimetric coverage (83.8 to 27.5 mrad)
Use LCAL to measure pairs and track fast luminosity changes - Provide hermetic calorimetric coverage (30 to 5.4 mrad)
Continue analysis of ee -> WW and ee -> Wen processes for polarization information
BeamCal performance study and conceptual design
Experimental tests of compact optics
Electrostatic separator experimental tests in harsh environment, up to 500 GeV/beam, feasibility and reliability
Experimental verification of backscattered photons in multi-bunch accelerator environment
Experimental verification of photon-photon collisions
Collimator material damage tests
Collimator wakefield tests
BPM tests in IR-like environment
Pair monitor prototype beam test in ESA
Prototype IR in ESA
BPM tests at ESA and ATF
Develop “disrupted” and “pairs” beam capability at ESA
EMI Test of VXD and Detector electronics
Collimation Study
Tail-folding study
Collimation system performance study
Re-estimate of beam halo and decision on halo/beam fraction collimation system and shielding will be designed to handle
Muon backgrounds
Study backgrounds caused by main beam and halo as a function of crossing angle and extraction scheme
Septum damage and background studies
Detector background analyses: Core Beam, Halo & SR
Recalculation of all detector backgrounds once CDR version of IR Layouts are finalized
Study of engineering layouts and conflicts
Develop & prototype Interferometric network for specific areas (e.g. energy spectrometer)
Collimator material damage analysis
Prototype collimators-exotic
Prototype collimators-traditional
Engineering study/prototypes any auxiliary vibration suppression system that can substantially reduce risk due to relative vibrati
Engineering design & prototype BDS (not IR) quad supports and movers
Document lengths, part counts, power requirements for working BDIR model
Engineering study of compact SC quad
Prototype of compact SC quad
Engineering study of compact PM quad
Prototype of compact PM quad
Engineering study of large aperture traditional SC quad
Prototype of large aperture traditional SC quad
Study of gamma-gamma backgrounds vs. crossing angle
Mechanical design of optical cavity for g-g laser
Experimental test of g-g drive laser
Experimental test of g-g mirror stability, damage
Experimental test of g-g optical cavity
Measurement of spin precession through existing bending magnets to extract the integrated bending field used is a spectromet
Track relative changes in energy distribution by measuring the spent beam
Develop & prototype & beam test cavity BPM for pre-IP energy spectrometer
Develop & prototype & beam test large aperture BPMs for BDS
Laser wire prototypes & tests
Develop & prototype & beam test BPMs for IR
Develop next generation nanometer scale beam size monitor
Develop conceptual plan for post-IP energy spectrometer
Laser wire design, prototypes & tests
SLC style wire scanner design, prototypes, & test
Shintake laser interferometer design, prototypes & tests
Conceptual design of Pre-IP and Post-IP compton polarimeters
Design, prototypes & tests of a RF cavity to provide time-dependent kick allowing to extract bunch length from transverse size
Beam position monitors based on cavity
Beam position monitors based on stripline and on cavity
Study of tuning techniques
Study effect of S-shaped bunches on Luminosity stabilization
Study of integrated feedback system performance
Feasibility study of RF cavity for angle feedback
Luminosity diagnostic study
Optimize LUM by using beam-beam deflections, pairs and BDS trajectory measuremnts
Experimental measurements of quad stability in linac cryostat
Experimental measurements of cold mass stability in SC Final Quad
Study utility/location of a Shintake style laser interferometer
Pair monitor performance study and conceptual design
L* Study
Crab cavity prototype tests of phase control and stability
Agree on working model (Strawman) for IR Layout for both IRs
Conceptual IR Engineering design
Detailed IR Engineering design
Agree on working BDIR model
Assemble and release internally consistent set of BDIR decks describing working BDIR model
Extraction Line Design
Solenoid compensation study
Study of impact of last drift space before detector required for zero or very small crossing angle designs
Design of final doublet or quadruplet
Study of final focus philosophy
Study of multi-TeV upgrade modifications
Study effect of wakefields in BDS
Design of Optically matched spin rotators in RTL sections
Conceptual Beam Dump engineering design
Impact of apertures on SUSY
Estimate uncertainty in rate of incoherent pair production and impact on VXD-Layer 1
Continue study of how shape of bhabha energy distribution as measured in forward calorimeters is measure of cms Energy
Continue study of how to infer CMS energy from measurements of radiative returns to the Z [ee -> (Z -> ll,qq) g]
Continue study of how to infer the event boost which results from the ISR and beamstrahlung using measurements of the acolli
Define energy measurement scenario using the complementary information from beam and physics measurements
Use LAT to measure Bhabha cross-section - Provide hermetic calorimetric coverage (83.8 to 27.5 mrad)
Use LCAL to measure pairs and track fast luminosity changes - Provide hermetic calorimetric coverage (30 to 5.4 mrad)
Continue analysis of ee -> WW and ee -> Wen processes for polarization information
BeamCal performance study and conceptual design
Experimental tests of compact optics
Electrostatic separator experimental tests in harsh environment, up to 500 GeV/beam, feasibility and reliability
Experimental verification of backscattered photons in multi-bunch accelerator environment
Experimental verification of photon-photon collisions
Collimator material damage tests
Collimator wakefield tests
BPM tests in IR-like environment
Pair monitor prototype beam test in ESA
Prototype IR in ESA
BPM tests at ESA and ATF
Develop “disrupted” and “pairs” beam capability at ESA
EMI Test of VXD and Detector electronics
Collimation Study
Tail-folding study
Collimation system performance study
Re-estimate of beam halo and decision on halo/beam fraction collimation system and shielding will be designed to handle
Muon backgrounds
Study backgrounds caused by main beam and halo as a function of crossing angle and extraction scheme
Septum damage and background studies
Detector background analyses: Core Beam, Halo & SR
Recalculation of all detector backgrounds once CDR version of IR Layouts are finalized
Study of engineering layouts and conflicts
Develop & prototype Interferometric network for specific areas (e.g. energy spectrometer)
Collimator material damage analysis
Prototype collimators-exotic
Prototype collimators-traditional
Engineering study/prototypes any auxiliary vibration suppression system that can substantially reduce risk due to relative vibrati
Engineering design & prototype BDS (not IR) quad supports and movers
Document lengths, part counts, power requirements for working BDIR model
Engineering study of compact SC quad
Prototype of compact SC quad
Engineering study of compact PM quad
Prototype of compact PM quad
Engineering study of large aperture traditional SC quad
Prototype of large aperture traditional SC quad
Study of gamma-gamma backgrounds vs. crossing angle
Mechanical design of optical cavity for g-g laser
Experimental test of g-g drive laser
Experimental test of g-g mirror stability, damage
Experimental test of g-g optical cavity
Measurement of spin precession through existing bending magnets to extract the integrated bending field used is a spectromet
Track relative changes in energy distribution by measuring the spent beam
Develop & prototype & beam test cavity BPM for pre-IP energy spectrometer
Develop & prototype & beam test large aperture BPMs for BDS
Laser wire prototypes & tests
Develop & prototype & beam test BPMs for IR
Develop next generation nanometer scale beam size monitor
Develop conceptual plan for post-IP energy spectrometer
Laser wire design, prototypes & tests
SLC style wire scanner design, prototypes, & test
Shintake laser interferometer design, prototypes & tests
Conceptual design of Pre-IP and Post-IP compton polarimeters
Design, prototypes & tests of a RF cavity to provide time-dependent kick allowing to extract bunch length from transverse size
Beam position monitors based on cavity
Beam position monitors based on stripline and on cavity
Study of tuning techniques
Study effect of S-shaped bunches on Luminosity stabilization
Study of integrated feedback system performance
Feasibility study of RF cavity for angle feedback
Luminosity diagnostic study
Optimize LUM by using beam-beam deflections, pairs and BDS trajectory measuremnts
Experimental measurements of quad stability in linac cryostat
Experimental measurements of cold mass stability in SC Final Quad
Study utility/location of a Shintake style laser interferometer
Pair monitor performance study and conceptual design
L* Study
Crab cavity prototype tests of phase control and stability
Agree on working model (Strawman) for IR Layout for both IRs
Conceptual IR Engineering design
Detailed IR Engineering design
Agree on working BDIR model
Assemble and release internally consistent set of BDIR decks describing working BDIR model
Extraction Line Design
Solenoid compensation study
Study of impact of last drift space before detector required for zero or very small crossing angle designs
Design of final doublet or quadruplet
Study of final focus philosophy
Study of multi-TeV upgrade modifications
Study effect of wakefields in BDS
Design of Optically matched spin rotators in RTL sections
Conceptual Beam Dump engineering design
Impact of apertures on SUSY
Estimate uncertainty in rate of incoherent pair production and impact on VXD-Layer 1
Continue study of how shape of bhabha energy distribution as measured in forward calorimeters is measure of cms Energy
Continue study of how to infer CMS energy from measurements of radiative returns to the Z [ee -> (Z -> ll,qq) g]
Continue study of how to infer the event boost which results from the ISR and beamstrahlung using measurements of the acolli
Define energy measurement scenario using the complementary information from beam and physics measurements
Use LAT to measure Bhabha cross-section - Provide hermetic calorimetric coverage (83.8 to 27.5 mrad)
Use LCAL to measure pairs and track fast luminosity changes - Provide hermetic calorimetric coverage (30 to 5.4 mrad)
Continue analysis of ee -> WW and ee -> Wen processes for polarization information
BeamCal performance study and conceptual design
gth from transverse size




risk due to relative vibration of magnets
designed to handle




risk due to relative vibration of magnets




ield used is a spectrometre - The claim is that reduced requirements on BPMs result because larger bend angles and drifts can be used - A




gth from transverse size
easure of cms Energy

 easurements of the acollinearity in Bhabha events
measurements

ge (30 to 5.4 mrad)
designed to handle




risk due to relative vibration of magnets




ield used is a spectrometre - The claim is that reduced requirements on BPMs result because larger bend angles and drifts can be used - A




gth from transverse size
easure of cms Energy

 easurements of the acollinearity in Bhabha events
measurements

ge (30 to 5.4 mrad)




 designed to handle




 risk due to relative vibration of magnets
ield used is a spectrometre - The claim is that reduced requirements on BPMs result because larger bend angles and drifts can be used - A




gth from transverse size
easure of cms Energy

 easurements of the acollinearity in Bhabha events
measurements

ge (30 to 5.4 mrad)




 designed to handle




 risk due to relative vibration of magnets
 ield used is a spectrometre - The claim is that reduced requirements on BPMs result because larger bend angles and drifts can be used - A




 gth from transverse size




easure of cms Energy

 easurements of the acollinearity in Bhabha events
measurements

ge (30 to 5.4 mrad)
designed to handle




risk due to relative vibration of magnets




ield used is a spectrometre - The claim is that reduced requirements on BPMs result because larger bend angles and drifts can be used - A




gth from transverse size
easure of cms Energy

 easurements of the acollinearity in Bhabha events
measurements

ge (30 to 5.4 mrad)
designed to handle




risk due to relative vibration of magnets




ield used is a spectrometre - The claim is that reduced requirements on BPMs result because larger bend angles and drifts can be used - A




gth from transverse size
easure of cms Energy

 easurements of the acollinearity in Bhabha events
measurements

ge (30 to 5.4 mrad)




 designed to handle




 risk due to relative vibration of magnets
ield used is a spectrometre - The claim is that reduced requirements on BPMs result because larger bend angles and drifts can be used - A




gth from transverse size
easure of cms Energy

 easurements of the acollinearity in Bhabha events
measurements

ge (30 to 5.4 mrad)




 designed to handle




 risk due to relative vibration of magnets
 ield used is a spectrometre - The claim is that reduced requirements on BPMs result because larger bend angles and drifts can be used - A




 gth from transverse size




easure of cms Energy

 easurements of the acollinearity in Bhabha events
measurements

ge (30 to 5.4 mrad)
nd angles and drifts can be used - A prerequisite of this method is polarisation of both beams
nd angles and drifts can be used - A prerequisite of this method is polarisation of both beams
nd angles and drifts can be used - A prerequisite of this method is polarisation of both beams
nd angles and drifts can be used - A prerequisite of this method is polarisation of both beams
nd angles and drifts can be used - A prerequisite of this method is polarisation of both beams
nd angles and drifts can be used - A prerequisite of this method is polarisation of both beams
nd angles and drifts can be used - A prerequisite of this method is polarisation of both beams
nd angles and drifts can be used - A prerequisite of this method is polarisation of both beams

								
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