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Reliable Data Transport in Wireless Networks

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Title: Reliable Data Transport in Wireless Networks


1
Reliable Data Transport in Wireless Networks
  • Anna Brunstrom
  • Dept. of Computer Science
  • Karlstad University

2
Outline
  • Introduction
  • TCP Basics
  • Challanges and Proposed Enhancements
  • Personal Reflections
  • SCTP
  • Conclusions

3
Introduction
  • Explosive growth of the Internet
  • Thin waist behind the success
  • Design based on end-to-end principle
  • TCP dominant transport protocol

4
TCP Basics
5
Reliable Data Transfer in TCP
  • Based on retransmission of lost packets
  • A timer is started when a packet is sent
  • Dynamically calculated based on RTT
  • When the packet arrives at the receiver a
    cumulative acknowledgment (ACK) is sent
  • End-to-end semantics
  • If an ACK is not received in time, then the
    packet is retransmitted
  • Exponential backoff of timer
  • Fast retransmit rule - three duplicate ACKs
    trigger retransmission

6
TCP Flow and Congestion Control
  • Window based control
  • Send rate limited by minimum of
  • Receivers advertised window
  • Congestion window
  • Estimates bandwidth based on probing
  • Assumes that packet loss indicates congestion

7
TCP Flow and Congestion Control
  • Slow start
  • Cwnd grows exponentially
  • Ends when cwnd reaches slow-start threshold
  • Congestion avoidance
  • Cwnd grows linearly
  • Fast recovery
  • Works in conjunction with fast retransmit
  • Avoids slow start after single packet loss

8
Timeout Scenario
After timeout
cwnd 20
ssthresh 10
ssthresh 8
9
Fast Retransmit Scenario
After fast recovery
Rwnd
10
Many TCP Variants
  • TCP Tahoe
  • Slow start, congestion avoidance, fast retransmit
  • TCP Reno
  • Slow start, congestion avoidance, fast
    retransmit, fast recovery
  • TCP New-Reno
  • Stay in fast recovery until all packet losses in
    window are recovered
  • Can recover 1 packet loss per RTT without causing
    a timeout
  • Selective Acknowledgements (SACK)
  • Provides information about out-of-order packets
    received by receiver
  • Can recover multiple packet losses per RTT

11
Challanges and Proposed Enhancements
The information superhighway of wireline
communications
The rocky road of mobile radio communications
vs
12
Challenges
  • Fundamental differences between wired and
    wireless communication
  • Channel errors
  • Due to interference, multipath fading etc.
  • Mobility
  • Handoff may cause packet loss and delay
  • Route failures and disconnections in MANETs
  • Channel contention (Ad hoc networks)
  • Hidden terminal and exposed terminal problems

13
TCP suffers because
  • Transmission problems at the phys/link layer and
    handoff/route failures due to mobility can lead
    to packet loss
  • Packet loss invokes congestion control at the
    sender
  • Exponential backoff entered for multiple losses
  • Spurious timeouts may occur when RTT fluctuates
  • High sending rate can cause channel contention

14
Proposed Optimizations
  • At the link layer
  • Split connection
  • Explicit notification/ cross layer
  • End to end

15
Link Layer Error Recovery
  • Shields upper layers (e.g. TCP) from errors that
    can be recovered at lower layers
  • Errors recovered locally
  • Reliable link layer beneficial to TCP
  • If it provides (almost) in-order delivery
  • If TCPs retransmission timeout is large enough
    to accommodate for variable delays due to link
    layer retransmissions

16
Impact of Link Layer ARQ
15 packet loss ?
17
Matching TCP Retransmissions
18
Link layer Examples
  • Snoop Balakrishnan95
  • TCP-aware link layer
  • Detect packet losses on wireless link, BS
    performs local retransmissions
  • Prevents fast retransmit by supressing dupACKs at
    BS
  • Does not work with encrypted IP-payload (e.g.
    IPSec)
  • TCP SACK-Aware Snoop Vangala03
  • Reliable link layer available in most modern
    wireless networks

19
Split connection
  • E2E TCP connection split into one connection on
    wired part of route and one over wireless part
  • Hides transmission errors from sender, local
    recovery
  • Primary responsibility at base station
  • If specialized transport protocol used on
    wireless, then wireless host also needs
    modification
  • Breaks end-to-end semantics

20
Split connection Examples
  • Indirect TCP (I-TCP) Bakre97
  • Standard TCP connection over both hops
  • Mainly used for mobility (transfer state between
    BSs)
  • WAP
  • Own networking stack to gateway/proxy
  • WAP2.0 can use native TCP
  • Split TCP Kopparty02
  • Split long TCP connections into localized
    segments to deal with frequent route failures in
    MANETs

21
Explicit notification
  • A node determines whether packets are lost for
    reasons other than congestion and informs sender
  • Sender can retransmit packet without invoking
    congestion control
  • Motivated by Explicit Congestion Notification
    (ECN) proposal
  • Proposed solutions differ in
  • Who sends explicit notification
  • How they decide to send explicit notification
  • What sender does on receiving notification

22
Explicit notification Examples
  • Partial Acknowledgements Biaz97
  • Sender gets partial ack from base station, and
    normal ack from receiver -gt wireless losses can
    be differentiated
  • Checksum Based Loss Notification Garcia02
  • Detect corrupt TCP checksum, notify sender via
    new TCP option
  • Explicit Link Failure Notification Holland02
  • Targets ad hoc networks
  • Piggyback notification onto DSRs route failure
    message to sender
  • TCP sender disables congestion control until
    route is fixed

23
Checksum Based LN Example
Bandwidth 1 Mbps, 10 ms delay
24
End to end optimizations
  • Only end node(s) are modified
  • Receiver-based scheme
  • Receiver infers cause of packet loss or other
    event
  • Explicitly or implicitly informs the sender
  • Sender-based scheme
  • Sender attempts to determine cause of packet loss

25
End to end optimizations Examples
  • TCP Westwood/Westwood Casetti02
  • Use rate of packets to estimate available
    bandwidth instead of probing
  • JTCP Wu04
  • Uses loss predictor based on the interarrival
    jitter to distinguish congestion and wireless
    losses
  • Freeze-TCP Goff00
  • When handover is about to happen, send a packet
    with receiver window set to zero to freeze
    transmissions
  • Dynamic Delayed ACK Altman03
  • Reduce contention on the wireless channel by
    reducing the number of ACKs, ACK generation
    frequency set dynamically

26
Personal Reflections
27
Balanced View of Problem
  • TCP works quite well in many wireless networks
  • A reliable link layer goes a long way
  • TCP fairly robust to delay variations
  • Consider the time scales
  • Requires
  • Accurate models of wireless networks
  • Accurate models of TCP
  • Compare with relevant version

28
Impact of Buffering
  • Not well understood
  • Often neglected in studies
  • Still influences results
  • Trend towards smaller buffers
  • Some examples of work on this
  • AQM method for 3G networks, aim for single packet
    drop in TCP window SÃ¥gfors03
  • Apply RED to UMTS RLC buffer, pace ACKs depending
    on buffer occupancy Alcaraz06

29
Example Buffering in GPRS
30
Consider Short Flows
  • Common assumption of bulk transfers
  • Most TCP flows are short
  • Loss recovery can be more important than
    congestion control

31
SCTP
32
Stream Control Transmission Protocol
  • Standardized for carrying signaling traffic over
    IP
  • Defined as a general purpose protocol
  • Like TCP, SCTP
  • is connection-oriented (association)
  • provides a reliable transport service
  • uses window-based congestion control
  • Unlike TCP, SCTP
  • is message oriented
  • supports multiple concurrent data streams
  • supports the concept of multihoming
  • supports unordered messages

33
Multihoming
  • Multiple IP addresses at each endpoint for a
    single association
  • Originally defined for link redundancy
  • Extensions increased performance by load
    balancing
  • mobility management at transport layer

34
AISLE (autonomic interface selection)
  • When congestion detected consider switching to
    secondary path
  • Based on bandwidth and capacity estimates
  • Time hysterisis to avoid ping-pong effects

Casetti06
35
Conclusions
36
Conclusions
  • Wireless communication different from wireline
    communications
  • A large number of TCP optimizations proposed
  • Small subset illustrated
  • Based on some general principles
  • No single right solution
  • But after all, TCP works quite ok
  • SCTP
  • Adds some new features
  • Multihoming

37
?
38
References
  • H. Balakrishnan, S. Seshan, and R. H. Katz,
    Improving Reliable Transport and Handoff
    Performance in Cellular Wireless Networks, ACM
    Wireless Networks, vol. 1, no. 4, Nov. 1995, pp.
    469481.
  • S. Vangala and M. Labrador, The TCP
    SACK-Aware-Snoop Protocol for TCP over Wireless
    Networks, IEEE VTC, Orlando, FL, vol. 4, Oct.
    2003, pp. 2624283.
  • A. V. Bakre , B. R. Badrinath, Implementation and
    Performance Evaluation of Indirect TCP, IEEE
    Transactions on Computers, v.46 n.3, p.260-278,
    March 1997
  • S. Kopparty, S.V. Krishnamurthy, M. Faloutsos,
    S.K. Tripathi, "Split-TCP for Mobile Ad Hoc
    Networks", Proceedings of IEEE GLOBECOM, Taipei
    2002.
  • S. Biaz, M. Mehta, S. West and N. Vaidya, "TCP
    over Wireless Networks Using Multiple
    Acknowledgments", Technical Report 97-001, Texas
    AM University, Jan. 1997.
  • J. Garcia and A. Brunstrom, Checksum-based Loss
    Differentiation, Proceedings 4th IEEE Conference
    on Mobile and Wireless Communications Networks
    (MWCN 2002), Stockholm, Sweden, September 2002.
  • G. Holland and N. Vaidya, Analysis of TCP
    Performance over Mobile Ad Hoc Networks, ACM
    Wireless Networks, vol. 8, no. 2, Mar. 2002, pp.
    27588.

39
References
  • S. Mascolo, C. Casetti, M. Gerla, M. Y. Sanadidi
    and R. Wang, TCP Westwood Bandwidth Estimation
    for Enhanced Transport over Wireless Links,
    Proc. of the ACM Mobicom 2001, Rome, Italy, July
    16-21 2001.
  • E. H. K. Wu and M. Z. Chen, JTCP Jitter-Based
    TCP for Heterogeneous Wireless Networks, IEEE
    JSAC, vol. 22, no. 4, May 2004, pp. 75766
  • T. Goff et al., Freeze-TCP A True End-to-End
    TCP Enhancement Mechanism for Mobile
    Environments, IEEE INFOCOM, vol. 3, Apr. 2000,
    pp. 153745.
  • E. Altman and T. Jimenez, Novel Delayed ACK
    Techniques for Improving TCP Performance in
    Multihop Wireless Networks, Proc. Pers. Wireless
    Commun., Venice, Italy, Sep. 2003, pp. 23753.
  • M. SÃ¥gfors, R. Ludwig, M. Meyer and J. Peisa,
    "Queue Management for TCP Traffic over 3G Links",
    IEEE WCNC 2003, New Orleans, USA, March 2003
  • C. Casetti, C. F. Chiasserini, R. Fracchia, M.
    Meo, AISLE Autonomic Interface SeLEction for
    Wireless Users, IEEE WoWMoM 2006, Niagara-Falls,
    Buffalo-NY, 26-29 June 2006
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