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Tsung-Chin Shih 、 Tsung-Chin Shih 、 Shun-Ren Yang National Tsing Hua University, Hsinchu, Taiwan, R.O.C. IEEE IWCMC 2011 A Cooperative MAC Protocol in.

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Presentation on theme: "Tsung-Chin Shih 、 Tsung-Chin Shih 、 Shun-Ren Yang National Tsing Hua University, Hsinchu, Taiwan, R.O.C. IEEE IWCMC 2011 A Cooperative MAC Protocol in."— Presentation transcript:

1 Tsung-Chin Shih 、 Tsung-Chin Shih 、 Shun-Ren Yang National Tsing Hua University, Hsinchu, Taiwan, R.O.C. IEEE IWCMC 2011 A Cooperative MAC Protocol in Multi-Channel Wireless Ad Hoc Networks

2 Outline Introduction Goal Background The proposed protocol Simulation Conclusion

3 Introduction Many multichannel MAC protocols are designed to support parallel data transmissions on different frequency channels Dedicate Control Channel Spilt Phase Common Hopping Parallel Rendezvous

4 Introduction Single transceiver constraint In a multi-channel multi-hop environment, a hop cannot receive data and simultaneously forward data Cooperative communication

5 Goal We propose a SSCH-based protocol Incorporates the notion of cooperative communication into multi-channel MAC protocols Allowing a single transceiver to achieve the enhanced network capacity and reduced packet delay

6 Background SSCH: Introduction SSCH is one of the Parallel Rendezvous protocols Slotted Seeded Channel Hopping (SSCH) A new channel hopping protocol Increases network capacity using multiple channels Overcomes limitations of dedicated control channel

7 Background SSCH: Slots and Seeds Divide time into slots 3 channels 1 02 1 02 1 0 01201201 New Channel = (Old Channel + seed) mod (Number of Channels) seed is from 1 to (Number of Channels - 1) Seed = 2 Seed = 1 (1 + 2) mod 3 = 0 (0 + 1) mod 3 = 1 A B

8 Background SSCH: Syncing Seeds 3 channels 1 02102 1 0 0121021 0 Seed Follow A: Change next (channel, seed) to (2, 2) A B 22 222 2 22 11 2 22222 2 2 1 B wants to start a flow with A 2

9 Background SSCH: Partial Synchronization Syncing to multiple nodes A sends packets to B & C Each node has multiple seeds Each seed can be synced to a different node If the number of channels is 3, and a node has 2 seeds: 1 and 2 221010221100 (1 + 1) mod 3 = 2 (2 + 2) mod 3 = 1 (2 + 1) mod 3 = 0 (1+ 2) mod 3 = 0

10 Background Illustration of the SSCH Protocol

11 The proposed protocol All the nodes use IEEE 802.11a as they do in the experimental configuration in SSCH There are N available channels, all of equal bandwidth and no channel overlaps any other Each node is equipped with a single half-duplex transceiver

12 The proposed protocol Relay Selection Channel Assignment

13 The proposed protocol Relay Selection Channel Reservation Cooperative Ready-To-Send (C-RTS) Relay Contention Cooperative Clear-To-Send (C-CTS) Data Transmission

14 The proposed protocol Three Scenarios Case 1: A, B, and D are all on the same channel Case 2: A and D are on the same channel, but B is on a different one. Case 3: A and B are on the same channel, but D is on a different one New coordination handshake

15 The proposed protocol Channel Assignment 121211212121 Node D Seeds 021120012210

16 Simulation

17 Grid Topology Our proposed protocol Naive protocol Line Topology Only A, B, C, D, and E are in the line topology Single-bottleneck Topology This topology is like a grid topology, but H and K disappear C creates a bottleneck of this path in our protocol

18 Simulation NONCOOP Non-cooperative multi-channel MAC protocol (SSCH) COOP Our proposed cooperative multi-channel MAC protocol Naive COOP Naive cooperative multi-channel MAC protocol

19 Simulation Grid Topology

20 Simulation Line Topology

21 Simulation Single-bottleneck Topology

22 Conclusion Our proposed protocol achieves a higher network capacity and lower packet delay The overhead of the proposed relay node selection approach is significantly small

23 Thank You

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