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Cheng- Kuan Hsieh, Jyh -Cheng Chen, Jeng-Feng Weng

Cooperative Adaptive Partner Selection for Real-Time Services in IEEE 802.16j Multihop Relay Networks. Cheng- Kuan Hsieh, Jyh -Cheng Chen, Jeng-Feng Weng Department of Computer Science, National Tsing Hua University , Hsinchu , Taiwan. IEEE WCNC 2010. Outline. Introduction Problem

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Cheng- Kuan Hsieh, Jyh -Cheng Chen, Jeng-Feng Weng

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  1. Cooperative Adaptive Partner Selection for Real-Time Services in IEEE 802.16j MultihopRelay Networks Cheng-KuanHsieh, Jyh-Cheng Chen, Jeng-FengWeng Department of Computer Science, National TsingHua University,Hsinchu, Taiwan IEEEWCNC2010

  2. Outline • Introduction • Problem • Goals & Assumptions • CAPS Algorithm • Simulations • Conclusions

  3. Introduction • IEEE 802.16e is a promising standard for mobile Broadband Wireless Access (BWA) • Base Station (BS) • Mobile Stations (MSs) • IEEE 802.16j is defined for Multihop Relay (MR) operations • Base Station (BS) • Mobile Stations (MSs) • Relay Stations (RSs)

  4. Introduction • IEEE 802.16j MR network architecture Relay link: between an MR-BS and an RS between two RSs Access link: between an RS and an MS between an MR-BS and an MS

  5. Introduction • IEEE 802.16j provides real-time services for multi-hop users • Bandwidth resource is allocated to each intermediate hop along the path between the MS and the MR-BS • Real-time services require the strict QoS requirement • UGS/rtPS/ertPS RS3 RS1 BS MS RS2

  6. Introduction • IEEE 802.16j provides real-time services for multi-hop users • The MS doesn’t need to request bandwidth for each packet in each hop. • Therefore overhead is eliminated and packet latency is reduced. RS3 RS1 BS MS RS2

  7. Problem • An MS suffers from bad channel and cannot transmit packets to its access RS correctly • all bandwidths allocated from the access RS to the MR-BS along the multihop path are wasted. • Existing researches all focus on how to select a best path from MR-BS to an MS. • How to maintain the multi-hop connection when an MS experiences bad channel ? RS3 RS1 BS MS RS2

  8. Goals • An MS is currently experiencing bad channel condition • The QoS of real-time services could still be maintained by a good cooperative partner with good channel condition • How to design an algorithm to select a cooperative partner with best capability in IEEE 802.16j networks ? • Cooperative Adaptive Partner Selection (CAPS) algorithm • Select a partner with the most effective path RS3 RS1 BS MS RS2

  9. Assumptions • MR-BS maintains the location information of MSs. • On experiencing bad channel condition and cannot transmit packets to its access RS correctly, an MS can communication with its neighboring MSs.

  10. CAPS Algorithm • Cooperative Adaptive Partner Selection algorithm • Candidate selection phase • Partner selection phase

  11. CAPS Algorithm_Candidateselection phase • Error Detection • Initialization • MS’s Operation • Scheduling in MR-BS • Candidate Selection C:Cooperative candidates set C:Cooperative candidates set C={MS2, MS3, MS4 } C={MS2, MS3, MS4 } RS2 RS4 RS5 RS1 RS3 MS4 MS2 MS3 MS1 MS1 erroneous MS erroneous MS MR-BS

  12. CAPS Algorithm_Partnerselection phase • De:end-to-end delay • Dc:delay in the cooperative link RS5 RS2 RS4 RS3 RS1 MS4 MS2 MS3 MS1 MS1 erroneous MS Dc MR-BS De

  13. CAPS Algorithm_Partnerselection phase • Weighted Moving Average (WMA) • maintain a database (many De’s for different paths and many Dc’s for different links) • flush old data • keep n samples (old data may not reflect instantaneous delay)

  14. CAPS Algorithm_Partnerselection phase • Weighted Moving Average (WMA) WMADe4=38 RS1 RS4 RS2 RS3 RS5 WMADe2=43 WMADc2 = 21.9 MS2 MS3 MS1 MS4 MR-BS WMADe1=51 WMADc4 = 20.3 Dp4 = 38 + 17.3 = 55.3 Dp2 = 43 + 21.9 = 64.9 Dp3 = 51 + 20.3 = 71.3

  15. CAPS Algorithm_Partnerselection phase • Weighted Moving Average (WMA) WMADe4=38 RS5 RS2 RS4 RS3 RS1 WMADe2=43 MS1 MS4 MS2 MS3 MR-BS WMADe1=51 Dp4 = 38 + 17.3 = 55.3 Dp2 = 43 + 21.9 = 64.9 Dp3 = 51 + 20.3 = 71.3

  16. Simulations • Simulator:NS2 • Map size:5 km * 5 km • Packet size:150bytes • Bandwidth is allocated evenly to MSs because they generate the same traffic.

  17. Simulations • Simulation topology • 1MR-BS • 15RSs • 35 MSs

  18. Simulations • Average packet delay versus different PERs

  19. Simulations • Average jitter versus different PERs

  20. Simulations • Average packet loss rate versus different PERs

  21. Simulations • Throughput versus different PERs

  22. Conclusions • The MR-BS will selectan MS with minimum delay to help the erroneous MS. Therefore, the erroneous MS can still use other path totransmit packets to the MR-BS. • The results show CAPScan improve the performance significantly interms of the packet delay, jitter, packet loss rate, andthroughput.

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