TCP Performance in Wireless multi-hop Networks

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

Throughput as performance metric used

TCP throughput ussually less than optimal due to TCP senders inability to accurate determine the cause of a packet loss

TCP sender assumes that all packets losses are caused by congestion

When link on TCP route breaks, TCP sender reacts as if congestion was the cause, reducing its congestion window and, in instance of a timeout, backing-off its retransmission timeout (RTO)

Therefore, route changes due to host mobility can detrimental impact on TCP performance

To gauge impact of route changes on TCP perfomance, we derived an upper bound on TCP throughput, the expected throughput

TCP throughput measure obtained by simulation is then compared with expected throughput

Expected throughput was obtained as the following:
- 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 1 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

Our objective here is to use these measurements to determine expected troughput

Expected throughput is a function of mobility pattern

For instance, if two nodes are always adjacent and move together, the expected thoughput for the TCP connection between them would be identical to that for one hop in Table 1

expected throughput = ${\frac {\sum _{i=1}^{\infty }T_{i}*t_{i}}{\sum _{i=1}^{\infty }t_{i}}}$

Measurement of TCP-Reno Throughput

TCP throughput should monotonically degrade as speed increase

Throughput drops sharply as mean speed increased from 2 m/s to 10 m/s

When mean speed increase from 10 m/s to 20 m/s and 30 m/s th averaged over 50 runs decreases only sligthly

Counter intuitive result: In fact throughput could have potentially increased with speed

Following observations are to be seen: although, for any given speed, the points may be located near or far from the diagonal line (expected throughput), when speed is increased, the points tend to move away from the diagonal, signifying a degradation in th

For given speed, certain mobility patterns achieve th close to 0, although other mobility patterns (with the same mean speed) are able to achieve a higher throughput

Even at high speeds, some mobility patterns result in high throughput that is close to the expected throughput

If two nodes move together, the link between them will not break, regardless of their speed

Mobility Induced Behaviours

Observing examples of mobility induced behaviours

There are several possible explanations (due to the variety of used protocols, such as 802.11 MAC, ARP, DSR and TCP on top of them)

Throughput: Function of data acknowledged to the sender

Event	Time (secs)	Node	SeqNo	Pkt	Reason of dropping
s	0.000	1	1	tcp
D	0.191	5	1	tcp	NRTE
s	6.000	1	1	tcp
r	6.045	2	1	tcp
s	6.145	2	1	ack
D	6.216	21	1	ack	NRTE
s	18.000	1	1	tcp
s	42.000	1	1	tcp
s	90.000	1	1	tcp
D	120.000	15	1	tcp	END
D	120.000	16	1	tcp	END
D	120.000	25	1	tcp	END

TCP Performance in Wireless multi-hop Networks

Contents

Introduction

Simulation Environment and Methodology

Performance Metric

Measurement of TCP-Reno Throughput

Mobility Induced Behaviours

TCP Performance Using Explicit Feedback

Split-TCP

Conclusion

References

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TCP Performance in Wireless multi-hop Networks

Introduction

Simulation Environment and Methodology

Performance Metric

Measurement of TCP-Reno Throughput

Mobility Induced Behaviours

TCP Performance Using Explicit Feedback

Split-TCP

Conclusion

References

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