The Future of Broadband Wireless (and the role of awareness in ...

The Future of Broadband Wireless (and the role of “awareness” in wireless Internet performance) Carey Williamson iCORE Professor Department of Computer Science University of Calgary October 16, 2002 1 Introduction r It is an exciting time to be an Internet researcher (or even a user!) r The last 10 years of Internet development have brought many advances: m m m m m m World Wide Web (WWW) Media streaming applications “Wi-Fi” wireless LANs Mobile computing E-Commerce, mobile commerce Pervasive/ubiquitous computing 2 October 16, 2002 October 16, 2002 3 The Wireless Web r The emergence and convergence of these technologies enable the “wireless Web” m m m the wireless classroom the wireless workplace the wireless home r Holy grail: “anything, anytime, anywhere” access to information (when we want it, of course!) r My iCORE mandate: design, build, test, and evaluate wireless Web infrastructures October 16, 2002 4 Clarification “Wireless Communications” (the enabler) “Wireless Internet” (the value-added service) October 16, 2002 = 5 Internet Protocol Stack r Application: supporting network m applications and end-user services FTP, SMTP, HTTP, DNS, NTP Application r Transport: end to end data transfer m TCP, UDP r Network: routing of datagrams Transport Network from source to destination m IPv4, IPv6, BGP, RIP, routing protocols Data Link Physical r Data Link: hop by hop frames, m channel access, flow/error control PPP, Ethernet, IEEE 802.11b 001101011... r Physical: raw transmission of bits October 16, 2002 6 Pieces of the Puzzle r Portable computing devices: no problem r r r r (cell phones, PDAs, notebooks, laptops…) Wireless access: not much of a problem (BlueTooth, IEEE 802.11, 802.11b, “WiFi”, 802.11a, Pringles…) Security: still an issue, but being addressed Services: the next big growth area??? Performance transparency: providing an end-user experience that is hopefully no worse than that in traditional wired Internet desktop environments (my focus) 7 October 16, 2002 Research Theme r Existing layered Internet protocol stack does not lend itself well to providing optimal performance for diversity of service demands and environments r Who should bend: users or protocols? r Explore the role of “awareness” in Internet protocol performance r Identify tradeoffs, evaluate performance October 16, 2002 8 Talk Overview r Introduction r Background m Emerging Wireless Trends and Technologies m The Future of Broadband Wireless r The Role of “Awareness” m m m TCP 101 Motivating Examples Our Work on CATNIP r Concluding Remarks October 16, 2002 9 Brief History: Cellular/Wireless r First Generation (1G): analog (cellular voice, AMPS, RTMS, TACS, 1980’s) r Second Generation (2G): digital (IS-64, GSM, ISM-95, 8-32 kbps, 1990’s) 2.5G You are here (always on, UMTS, 334 kbps-2 Mbps, 2000’s) r Third Generation (3G): broadband multimedia October 16, 2002 10 Some Interesting Reading r Brave New Unwired World (BNUW), by Alex Lightman and William Rojas r In a nutshell, the authors argue that: m m 2.5G is dead 3G is a waste of time (and money) m 4G is EVERYTHING!!! 11 October 16, 2002 Another Lightman Opinion r “the success of a technology in the marketplace is inversely proportional to the amount of hype associated with that technology prior to its release” Examples: ISDN BlueTooth 3G Examples: Internet, Web, napster, WiFi October 16, 2002 12 What is 4G then? r Culmination of wireless Internet revolution r Convergence of key emerging technologies: Image Generation 802.11b Storage technology Semiconductors GPS Wearable Computers New Interfaces WIDs IP-based Networks Satellite Backhaul NWs Molecular Engineering Wireless Services October 16, 2002 Microprocessors Antenna Arrays RF elements NanoTech Quantum 13 Some Challenges/Opportunities r Ultra low-power processors: m pg 108: “could change the entire industry…” r Services: m pg 76: “extension of the Internet to mobile devices…whole new range of Internet services…personalized, location-sensitive content…previously impossible or impractical” r Awareness: m pg 221: “Location/context-aware applications… can determine and react to current physical computing context of mobile users… altering information presented to users accordingly” October 16, 2002 14 The Future? r Service-centric economy r Significant shifting of economic power r The “winner” is likely to be either Japan (iMODE, DoCoMo) or China (Internet growth, wireless growth) r Reasons: m m cooperation, encouragement, support from government on a national scale strategic alliances within and across industries October 16, 2002 15 Talk Overview r Introduction r Background m Emerging Wireless Trends and Technologies m The Future of Broadband Wireless r The Role of “Awareness” m m m TCP 101 Motivating Examples Our Work on CATNIP r Concluding Remarks October 16, 2002 16 My iCORE Research Team r Martin Arlitt: Web performance, r r r r r workload characterization Transport Qian Wu: TCP, ns-2 simulation Guangwei Bai: network traffic Network measurement and modeling Tianbo Kuang: wireless measurements, Data Link video compression, streaming media Nayden Markatchev: technical support Physical Grad Students: Mingwei Gong, Yujian Li, Kehinde Oladosu, Fang Xiao, Andreas Hirt, Abhinav Gupta, Gwen Houtzager October 16, 2002 Application 17 Internet Protocol Stack r Application: supporting network m applications and end-user services FTP, SMTP, HTTP, DNS, NTP Application r Transport: end to end data transfer m TCP, UDP r Network: routing of datagrams Transport Network from source to destination m IPv4, IPv6, BGP, RIP, routing protocols Data Link Physical r Data Link: hop by hop frames, m channel access, flow/error control PPP, Ethernet, IEEE 802.11b 001101011... r Physical: raw transmission of bits October 16, 2002 18 Viewpoint r “Layered design is good; layered implementation is bad” -Anon. r Good: m m unifying framework for describing protocols modularity, black-boxes, “plug and play” functionality, well-defined interfaces (good SE) r Bad: m increases overhead (interface boundaries) m compromises performance (ignorance) October 16, 2002 19 Research Theme r Existing layered Internet protocol stack does not lend itself well to providing optimal performance for diversity of service demands and environments r Who should bend: users or protocols? r Explore the role of “awareness” in Internet protocol performance r Identify tradeoffs, evaluate performance October 16, 2002 20 Tutorial: TCP 101 r The Transmission Control Protocol (TCP) is r r r r the protocol that sends your data reliably Used for email, Web, ftp, telnet, … Makes sure that data is received correctly: right data, right order, exactly once Detects and recovers from any problems that occur at the IP network layer Mechanisms for reliable data transfer: sequence numbers, acknowledgements, timers, retransmissions, flow control... 21 October 16, 2002 TCP 101 (Cont’d) r TCP is a connection-oriented protocol SYN SYN/ACK GET URL ACK YOUR DATA HERE FIN ACK October 16, 2002 FIN/ACK 22 TCP 101 (Cont’d) r TCP slow-start and congestion avoidance ACK October 16, 2002 23 TCP 101 (Cont’d) r TCP slow-start and congestion avoidance ACK October 16, 2002 24 TCP 101 (Cont’d) r TCP slow-start and congestion avoidance ACK October 16, 2002 25 TCP 101 (Cont’d) r This (exponential growth) “slow start” process continues until either of the following happens: m m packet loss: after a brief recovery phase, you enter a (linear growth) “congestion avoidance” phase based on slow-start threshold found all done: terminate connection and go home October 16, 2002 26 Simple Observation r Consider a big file transfer download: m brief startup period to estimate network bandwidth; most time spent sending data at the “right rate”; small added penalty for lost packet(s) r Consider a typical Web document transfer: m median size about 6 KB, mean about 10 KB m most time is spent in startup period; as soon as you find out the network capacity, you’re done! m if you lose a packet or two, it hurts a lot!!! October 16, 2002 27 The Problem (Restated) r TCP doesn’t realize this dichotomy between optimizing throughput (the classic file transfer model) versus optimizing transfer time (the Web document download model) r Wouldn’t it be nice if it did? (i.e., how much data it was sending, and over what type of network) r Some research starting to explore this... October 16, 2002 28 Motivating Example #1 r Wireless TCP Performance Problems Low capacity, high error rate Wireless Access Wired Internet High capacity, low error rate 29 October 16, 2002 Motivating Example #1 r Solution: “wireless-aware TCP” (I-TCP, ProxyTCP, Snoop-TCP, ...) October 16, 2002 30 Motivating Example #2 r Multi-hop “ad hoc” networking Janelle October 16, 2002 Carey 31 Motivating Example #2 r Multi-hop “ad hoc” networking Janelle Yannis October 16, 2002 Carey 32 Motivating Example #2 r Multi-hop “ad hoc” networking Janelle Yannis October 16, 2002 Carey 33 Motivating Example #2 r Multi-hop “ad hoc” networking Janelle Yannis October 16, 2002 Carey 34 Motivating Example #2 r Two interesting subproblems: m Dynamic ad hoc routing: node movement can disrupt the IP routing path at any time, disrupting TCP connection; yet another way to lose packets!!!; possible solution: Explicit Loss Notification (ELN) TCP flow control: the bursty nature of TCP packet transmissions can create contention for the shared wireless channel among forwarding nodes; possible solution: rate-based flow control 35 m October 16, 2002 Example of Our Work r Context-Aware Transport/Network Internet Protocol (CATNIP) r Motivation: “Like kittens, TCP connections are born with their eyes shut” - CLW 2002 r Research Question: How much better could TCP perform if it knew what it was trying to accomplish (e.g., Web document transfer)? 36 October 16, 2002 Some Key Observations (I think) r Not all packet losses are created equal r TCP sources have relatively little control r IP routers have all the power!!! October 16, 2002 37 Tutorial: TCP 201 r There is a beautiful way to plot and visualize the dynamics of TCP behaviour r Called a “TCP Sequence Number Plot” r Plot packet events (data and acks) as points in 2-D space, with time on the horizontal axis, and sequence number on the vertical axis October 16, 2002 38 SeqNum Key: X Data Packet + Ack Packet + X + X + X + X + X + X + X + + + + X X X X X + X X + + Time October 16, 2002 39 TCP 201 (Cont’d) r What happens when a packet loss occurs? r Quiz Time... m Consider a 14-packet Web document m For simplicity, consider only a single packet loss October 16, 2002 40 SeqNum Key: X Data Packet + Ack Packet + X + X + X + X + X + X + + + + ? X X X X X + X X + + Time October 16, 2002 41 SeqNum Key: X Data Packet + Ack Packet + X + X + X + X + X + X + + + + X + X X X X X + X X + + Time October 16, 2002 42 SeqNum Key: X Data Packet + Ack Packet X X X X X X X X + X X + + + + + + ? X X X + + + Time October 16, 2002 43 SeqNum Key: X Data Packet + Ack Packet X X X X X X + X +++ + + + X X X X X + X X + + + + + + Time October 16, 2002 44 SeqNum Key: X Data Packet + Ack Packet ? X + X + Time October 16, 2002 45 SeqNum Key: X Data Packet + Ack Packet X X X X X X X X X + X + ++ + X + + + + + + Time October 16, 2002 46 TCP 201 (Cont’d) r Main observation: m “Not all packet losses are created equal” r Losses early in the transfer have a huge adverse impact on the transfer latency r Losses near the end of the transfer always cost at least a retransmit timeout r Losses in the middle may or may not hurt, depending on congestion window size at the time of the loss October 16, 2002 47 The TCP Transfer “Pain Profile” Relative Transfer Time 1 SeqNum of the Single Lost Packet N October 16, 2002 48 Design of CATNIP • Can we make the TCP/IP protocols “smarter” about the specific job they are trying to do?  Yes. Convey application-layer context information to the TCP and IP layers Application Document Size Transport Packet Priority October 16, 2002 Network 49 Design of CATNIP (Cont’d) • Q: What could a TCP source do differently? • A: If it knew how much data it had to send, and how far along it was already, then maybe…  Rate-Based Pacing of the Last Window (RBPLW)  Early Congestion Avoidance (ECA)  Selective Packet Marking (SPM): Use the reserved high-order bit in the TCP header to convey packet priority information (high priority for the really crucial packets) October 16, 2002 50 Design of CATNIP (Cont’d) • Q: What could an IP router do differently? • A: If it knew which packets were the “painful” ones to lose, then the router could…  CATNIP-Good: give them preferential treatment, and avoid throwing them away (if possible) when congested  CATNIP-Bad: throw them away October 16, 2002 51 Simulation Evaluation • Network model: Client 1 Server 1 1.5 Mbps, 5 ms Client 2 Server 2 RouterS RouterC Client 99 Client 100 Server 10 October 16, 2002 52 Simulation Evaluation (Cont’d) • Web workload model:  100 clients, 10 different Web pages  Use empirically-observed distribution to determine the size, and the number of embedded images October 16, 2002 53 Simulation Evaluation (Cont’d) • Factors and Levels: Factor TCP IP Levels Reno, RBPLW, ECA, ECA+RBPLW, SPM DropTail, RED, CATNIP-Good, CATNIP-Bad, CATNIP-RED • Performance metrics:  transfer time for each Web page  packet loss ratio October 16, 2002 54 Simulation Results for DropTail Routers Reno/ RBPLW Reno Mean and Standard Deviation of Transfer Times ECA ECA/RBPLW October 16, 2002 55 Simulation Results for CATNIP-Good Routers Mean and Standard Deviation of Transfer Times Reno/DropTail SPM/Good October 16, 2002 56 Observations r Sources have relatively little control r IP routers have all the power r Adding context-awareness at the IP routers improves both mean and standard deviation of Web page transfer times r SPM and CATNIP-Good provide most of the benefit r Advantages of CATNIP are most prominent at low levels of IP packet loss (1-5%) October 16, 2002 57 Summary r There seem to be performance advantages to bending the rules regarding the Internet protocol stack layered model r The general notion of “awareness” needs to explored in a variety of contexts m wireless networks, ad hoc routing, TCP/IP, Web caching, mobile computing, adaptive applications, … r Many exciting issues to explore!! October 16, 2002 58 The Next Steps r Putting it all together: Web + Wireless r Wireless Internet Performance Lab (UofC) r Experimental Laboratory for Internet Systems and Applications (UofS/UofC,CFI) r Research Collaborations: m UofC, UofS, UofA, TRLabs, CS/ECE m Nortel? HP? Cisco? Agilent? Telus Mobility? October 16, 2002 59 The End: Question Time! r For more information: m Email: carey@cpsc.ucalgary.ca m URL: www.cpsc.ucalgary.ca/~carey r Many thanks to my research team and the TeleSim Research Group at the U of C r Special thanks to iCORE, NSERC, CFI, andTelus Mobility October 16, 2002 60