TCP Performance in Wireless multi-hop Networks: Difference between revisions

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<li>All results based on a network configuration consisting of TCP-Reno over IP on an [[WLAN|802.11 wireless network]], with routing provided by the [[RoutingProtocols|Dynamic Source Routing]] (DSR) protocol and BSDs ARP protocol (used to resolve IP adresses to MAC adresses)
<li>All results based on a network configuration consisting of TCP-Reno over IP on an [[WLAN|802.11 wireless network]], with routing provided by the [[RoutingProtocols|Dynamic Source Routing]] (DSR) protocol and BSDs ARP protocol (used to resolve IP adresses to MAC adresses)

<li>Objective was to observe TCPs performance in the presence of mobility inducted failures in a plausible network environment, for which any of the proposed mobile wireless ad hoc routing protocols would have sufficed

<li>Network model consists of 30 nodes in 1500x300 meter flat, rectangular area

<li>Nodes move according to random waypoint mobility model

<li>In random waypoint model each node x picks a random destination and speed in the area and travels to destination in straight line

<li>Once x arrives, it pauses, picks another destination and goes on

<li>No pause, so every node is always in moving

<li>All nodes communicate with identical half duplex wireless radios, which are modeld after 802.11 based Wave Lan wireless radios, with a bandwith of 2Mbps and nominal transmission radius of 250m

<li>TCP packet size was 1460bytes, maximum window was eight packets

<li>All simulation results based on average throughput of 50 scenarios or patterns

<li>Each pattern, generated randomly, designates the initial placement and heading of each of the nodes over simulated time

<li>Used same pattern for different mean speeds

<li>For a given pattern at different speeds, same sequence of movements (and link failures) occur

<li>Speed of each node is uniformly distributed in an interval of 0,9v - 1,1v for some mean speed v


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Revision as of 16:29, 30 January 2005

Introduction

  
  • Early research showed TCP suffers poor Performance in wireless networks because of packet losses and corruption caused by wireless inducted errors
  • Further studies searched for mechanism to improve TCP performance in cellular wireless systems
  • Other researches investigated other network problems that negativly affect TCP performance, such as bandwidth asymmetry and large round trip times, which are prevalent in satelite networks
  • During the presentaition we adress another network charackteristic that impacts TCP performance, which is common in mobile ad hoc networks: link failures due to mobility
  • First present performance analysis of standart TCP over mobile ad hoc networks
  • Then present analysis of the use of explicit notification techniques to counter the affects of link failures

    • Simulation Environment and Methodology

      
  • For simulations the ns network simulator from Lawrence Berkles National Laboratory was used, with extensions from the MONARCH project at Carnegie Mellon
  • Extensions include a set of mobile ad hoc network routing protocols, an implementation of BSDs ARP protocol, an 802.11 MAC Layer, a radio propagation model and mechanisms to model node mobility using pre-computed mobility patterns that are fed to the simulation at run time
  • No modifications were made to the simulator (accept minor bug fixes that were necessary)
  • All results based on a network configuration consisting of TCP-Reno over IP on an 802.11 wireless network, with routing provided by the Dynamic Source Routing (DSR) protocol and BSDs ARP protocol (used to resolve IP adresses to MAC adresses)
  • Objective was to observe TCPs performance in the presence of mobility inducted failures in a plausible network environment, for which any of the proposed mobile wireless ad hoc routing protocols would have sufficed
  • Network model consists of 30 nodes in 1500x300 meter flat, rectangular area
  • Nodes move according to random waypoint mobility model
  • In random waypoint model each node x picks a random destination and speed in the area and travels to destination in straight line
  • Once x arrives, it pauses, picks another destination and goes on
  • No pause, so every node is always in moving
  • All nodes communicate with identical half duplex wireless radios, which are modeld after 802.11 based Wave Lan wireless radios, with a bandwith of 2Mbps and nominal transmission radius of 250m
  • TCP packet size was 1460bytes, maximum window was eight packets
  • All simulation results based on average throughput of 50 scenarios or patterns
  • Each pattern, generated randomly, designates the initial placement and heading of each of the nodes over simulated time
  • Used same pattern for different mean speeds
  • For a given pattern at different speeds, same sequence of movements (and link failures) occur
  • Speed of each node is uniformly distributed in an interval of 0,9v - 1,1v for some mean speed v

    • Performance Metric

    Measurement of TCP-Reno Throughput

    Mobility Induced Behaviours

    TCP Performance Using Explicit Feedback

    Split-TCP

    Conclusion

    References

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