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Capacity of wireless ad-hoc networks

Capacity of wireless ad-hoc networks. By Kumar Manvendra October 31,2002. Outline. Problem definition What is meant by the “capacity” ? Why is it relevant ? What are the issues involved ? Example scenarios with various simulation environments Performance results Open problems

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Capacity of wireless ad-hoc networks

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  1. Capacity of wireless ad-hoc networks By Kumar Manvendra October 31,2002

  2. Outline • Problem definition • What is meant by the “capacity” ? • Why is it relevant ? • What are the issues involved ? • Example scenarios with various simulation environments • Performance results • Open problems • Summary • Future Work • References

  3. Problem Definition • Capacity of Ad-Hoc Wireless Networks • A measure of the amount of data that can be transmitted simultaneously in an ad-hoc wireless network • Alternative explanation: Lack of congestion losses and misrouting of packets • Problems • Overall capacity decreases with increase in non-local traffic and number of nodes because they have to forward each other’s packets • Spatial reuse doesn’t seem to help that much

  4. Factors influencing Capacity • Traffic Pattern • Random • Locality of Communication • Long Range Interference • Multiple antennas • End-to-end delays • Packet Size • Node Properties • Node distribution • Static / Mobile nodes • Communication Radius and area of the ad-hoc network

  5. Need to explain the issues involved • Gupta and Kumar[3] showed that for static nodes, as number of nodes per unit area,n, increase …the throughput per source-destination pair decreases like 1/SQRT(N)

  6. Example #1 : Capacity of a chain of nodes • MAC interference among a chain of nodes Inter-nodal distance = 200 ms 1 2 3 4 5 6 Radio Range of Node Interference Range of Node 4

  7. 1 2 3 4 5 6 Radio Range of Node (200 ms) Interference Range of Node 4 Example #1 : Capacity of a chain of nodes • MAC interference among a chain of nodes

  8. Example #1 : Capacity of a chain of nodes • MAC interference among a chain of nodes 1 2 3 5 6 4 Radio Range of Node(200 ms) Interference Range of Node 4(550 ms)

  9. Example #1 : Capacity of a chain of nodes • MAC interference among a chain of nodes 1 2 3 5 6 4 Radio Range of Node Radio Range of Node(200 ms) Interference Range of Node 4(550 ms)

  10. Example #1 : Capacity of a chain of nodes • MAC interference among a chain of nodes 1 2 3 5 6 4 Radio Range of Node Radio Range of Node(200 ms) Interference Range of Node 4(550 ms) Assuming radios of non-neighboring nodes do not interfere with each other

  11. Example #1 : Capacity of a chain of nodes • MAC interference among a chain of nodes Total Max. Channel Utilization = 1/3 1 2 3 5 6 4 Radio Range of Node Interference Range of Node 4 Assuming radios of non-neighboring nodes do not interfere with each other

  12. Example #1 : Capacity of a chain of nodes • MAC interference among a chain of nodes Total Max. Channel Utilization = 1/4 1 2 3 5 6 4 Radio Range of Node Interference Range of Node 4 Assuming interference range interfere with non-neighboring nodes

  13. Simulation Performance Results – single chain of nodes With Longer Chains, Utilization levels go substantially low. For a 1500 Byte packet size, it is as low as 15% 500 B 1500 B 64 B

  14. Simulation Performance Results – single chain of nodes With Longer Chains, Utilization levels go substantially low. For a 1500 Byte packet size, it is as low as 15% • 802.11 is incapable of discovering an optimal schedule of transmissions • Inherent unfairness because nodes at the end send in more packets than nodes in the middle can forward • Back-offs cause wastage 500 B 1500 B 64 B Mimics results from actual hardware testing also

  15. 2 3 6 Radio Range of Node Interference Range of Node 4 Analysis of Performance Results • With increase in the length , per node Interference increases. So, per node waste of bandwidth increases. For example, in the example above, Node #1’s send rate is 0.48 while nodes further along the link can only forward at the rate of 0.26-0.35 4 1

  16. 1 2 3 4 5 6 Radio Range of Node Interference Range of Node Analysis of Performance Results • Waste in terms of back-off Periods For Example : Node #1 wasted back-off time is 5.4% of total time

  17. Example #2 : Capacity of a regular lattice network • Two communication patterns Scenario #2 Scenario #1

  18. Example #2 : Capacity of a regular lattice network • Scenario #1 Internode Distance = 200 ms Interference radius = 550 ms Every third row can operate Without interference to give a Maximum throughput of 1/4 Thus flow in such a lattice network is expected (theoretically) to reach 1/12

  19. Performance Results for Lattice simulations Same inefficiencies as in chain list : Disproportionate traffic per node And wasted back - off time( close to 0.75%) 500 B 1500 B 60 B

  20. Example #2 : Capacity of a regular lattice network Traffic flow direction • Scenario #2 1) Optimal Scheduling possible with predetermined routes. 2) Overall throughput can be maximized (in theory) with one vertical flow in one time unit and horizontal flows in another

  21. Performance Analysis Possible Problem : Since each node has a single queue per flow, if a packet to be sent horizontally is waiting for contention, the packet to be sent vertically might lose its chance to be sent Wasted time due to Back-off as high as 2.25% 500 B 1500 B 60 B

  22. Example Scenario #3 : Random traffic random layout • Assuming total randomness of nodes placement and destination selection for each sending node. • Assuming pre-computed paths

  23. Performance Results – comparison with lattices 1500 Bytes packets Horizontal and vertical horizontal random Random networks have somewhat less capacity than lattices because more packets routed through the center of the network, and not enough spatial reuse

  24. Another Perspective :Load imposed due to network’s nodes • One-hop capacity depends upon the amount of spatial reuse possible in the network and depends upon • Number of nodes • Inter-nodal distance • Physical area covered in the network • Mathematical analysis : • For packet rate ,R,….communication radius, r And expected physical path length L One Hop Capacity of the network to send and forward packets C > n . R . (L/r) • Assuming uniform node density, D, and number of nodes ,n …Capacity, C is also equal to k(n/D) , where k is a constant. • Therefore, per node capacity , R(packet rate), is R < k(r/D)*(1/L) = (C/n) / (L/r)

  25. Factors influencing Capacity • Traffic Pattern • Random • Locality of Communication • Long Range Interference • Multiple antennas • End-to-end delays • Packet Size • Node Properties • Node distribution • Static / Mobile nodes • Communication Radius and area of the ad-hoc network

  26. Factors influencing Capacity • Traffic Pattern • Random • Locality of Communication • Long Range Interference • Multiple antennas • End-to-end delays • Packet Size • Node Properties • Node distribution • Static / Mobile nodes • Communication Radius and area of the ad-hoc network

  27. Factors influencing Capacity • Traffic Pattern • Random • Locality of Communication • Long Range Interference • Multiple antennas • End-to-end delays • Packet Size • Node Properties • Node distribution • Static / Mobile nodes • Communication Radius and area of the ad-hoc network

  28. Another Perspective :Load imposed due to network’s nodes • One-hop capacity depends upon the amount of spatial reuse possible in the network and depends upon • Number of nodes • Inter-nodal distance • Physical area covered in the network • Mathematical analysis : • For packet rate ,R,….communication radius, r And expected physical path length L One Hop Capacity of the network to send and forward packets C > n . R . (L/r) • Assuming uniform node density, D, and number of nodes ,n …Capacity, C is also equal to k(n/D) , where k is a constant. • Therefore, per node capacity , R(packet rate), is R < k(r/D)*(1/L) = (C/n) / (L/r)

  29. Recap • R = (C/n) / (L/r) • or Per Node Capacity = (Average One hope Capacity) / (Expected Path Length) Inference : As expected path length increases, the bandwidth available to each node decreases. Inference: Since capacity is determined by traffic patterns, the most capacity enhancing traffic pattern is strictly local because expected path length remains constant

  30. Recap • R = (C/n) / (L/r) • or Per Node Capacity = (Average One hope Capacity) / (Expected Path Length) Inference : As expected path length increases, the bandwidth available to each node decreases. Inference: Since capacity is determined by traffic patterns, the most capacity enhancing traffic pattern is strictly local because expected path length remains constant

  31. Effects of Mobility • If a wireless network with many users, authors contend that optimal strategy is to allocate the bandwidth to the user who can best use it. • Assumptions of asynchronous applications and high threshold of tolerable delays • On the above assumption, per node throughput can be kept constant • distributing packets to as many nodes as possible (each with difference time variance) • transmitting only when nodes are close together so as to minimize interference • And hence, probabilistically , maximizing the overall throughput

  32. Summary • Capacity in an ad-hoc wireless network depends upon the following : • Number of nodes • Density • Traffic pattern • Mobility • Communication radius/interference

  33. References • Capacity of Ad-Hoc wireless networks , Li, Blake, Couto, Lee, Morris • Mobility increases the capacity of ad-hoc wireless networks, Grossglauser, Tse • The Capacity of Wireless Networks, Gupta and Kumar

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