TCP Performance in Wireless multi-hop Networks: Difference between revisions
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<tr><td><b><i>Hops</i></b></td><td><b><i>Throughput (Kbps)</i></b></td><td rowspan=11> |
<tr><td><b><i>Hops</i></b></td><td><b><i>Throughput (Kbps)</i></b></td><td rowspan=11> |
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Table shows measured TCP throughput as a function of number of hops, averaged over ten runs<br> |
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Throughput decreases rapidly when number of hops is increased from 1, then stabilizes once the number of hops becomes large |
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<tr><td>1</td><td>1463.0</td></tr> |
<tr><td>1</td><td>1463.0</td></tr> |
Revision as of 14:57, 2 February 2005
Introduction
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Simulation Environment and Methodology
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Performance Metric
- First simulated a static (fixed) network of n nodes that formed a linear chain containing n-1 wireless hops - Nodes used 802.11 protocol for medium access - Then a one-way TCP data transfer was performed between the two nodes at the ends of the linear chain, and the TCP throughput was measured between these nodes |
Hops | Throughput (Kbps) |
Table shows measured TCP throughput as a function of number of hops, averaged over ten runs Throughput decreases rapidly when number of hops is increased from 1, then stabilizes once the number of hops becomes large |
1 | 1463.0 | |
2 | 729.0 | |
3 | 484.4 | |
4 | 339.9 | |
5 | 246.4 | |
6 | 205.2 | |
7 | 198.1 | |
8 | 191.8 | |
9 | 185.3 | |
10 | 182.4 |