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Cluster-Based Multi-Channel Communications Protocols in Vehicle Ad Hoc Networks

Cluster-Based Multi-Channel Communications Protocols in Vehicle Ad Hoc Networks. IEEE Wireless Communications october2006, vol.13 No. 5 指導老師:童曉儒 教授 報告人:張益瑞. Outline. INTRODUCTION SYSTEM ARCHITECTURE FUNCTIONS AND DESIGNS OF PROTOCOLS THE CLUSTER CONFIGURATION PROTOCOL

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Cluster-Based Multi-Channel Communications Protocols in Vehicle Ad Hoc Networks

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  1. Cluster-Based Multi-Channel Communications Protocols in Vehicle Ad Hoc Networks IEEE Wireless Communications october2006, vol.13 No. 5 指導老師:童曉儒 教授 報告人:張益瑞

  2. Outline • INTRODUCTION • SYSTEM ARCHITECTURE • FUNCTIONS AND DESIGNS OF PROTOCOLS • THE CLUSTER CONFIGURATION PROTOCOL • THE INTRACLUSTER COORDINATION AND COMMUNICATION PROTOCOL • SIMULATION EVALUATIONS • CONCLUSIONS

  3. INTRODUCTION(1/2) • What is DSRC(Dedicated ShortRange Communication)? • V2V-based VANETs and V2R-based VANETs. • The data transmitted over the VANETs can be classified into the real-time traffic and the non-real-time traffic.

  4. DSRC • DSRC/802.11p • The standard of 802.11p is based on IEEE 802.11a PHY layer and IEEE 802.11 MAC layer • Seven 10 MHz channels at 5.9GHz • one control channel and six service channels

  5. V2V-BASED VANETS AND V2R-BASED VANETS

  6. THE DATA TRANSMITTED OVER THE VANETS • real-time traffic • such as safety messages and video/audio signals • non-real-time traffic • such as e-maps and road/vehicle-traffic/weather information

  7. INTRODUCTION(2/2) • Our proposed scheme mainly consists of following three core protocols. • Cluster Configuration Protocol • Intracluster Coordination and Communication Protocol • Intercluster Communication Protocol

  8. SYSTEM ARCHITECTURE • Four Broadcasting Strategies • Probability-based • Location-based • Neighbor-based • Cluster-based

  9. FOUR BROADCASTING STRATEGIES • 1. Probability-based: • A given PDF determines the decision, for example depending on the number of copies a node has received. • The strategy is often dynamic. • PDF = probability distribution function

  10. PROBABILITY-BASED

  11. FOUR BROADCASTING STRATEGIES • Location-based • The selection criterion is the amount of additional area that would be covered by enabling a node to forward. • Some proposal also computes position prediction as useful input information.

  12. LOCATION-BASED

  13. FOUR BROADCASTING STRATEGIES • Neighbor-based • A node is selected depending on its neighbors status (for instance, the status concerns how a neighbor is connected to the network).

  14. NEIGHBOR-BASED

  15. FOUR BROADCASTING STRATEGIES • Cluster-based • Nodes are grouped in clusters represented by an elected cluster-head. Only cluster-heads forward packets. • Nodes in the same cluster share some features (e.g., relative speed in VANETs). • Reclustering on-demand or periodically.

  16. CLUSTER-BASED

  17. SYSTEM ARCHITECTURE

  18. SYSTEM ARCHITECTURE • Our proposed scheme handles the following three tasks • Cluster-membership management • Real-time traffic (such as safety messages delivery) • Non-real-time data communications (such as e-maps download, movies download, etc.)

  19. SYSTEM ARCHITECTURE

  20. 有限狀態機( FINITE STATE MACHINE, FSM) • 在現實中,有許多事情可以用有限個狀態來表達。 • 紅綠燈運作的原理相當簡單,從一開始綠燈,經過一段時間後,將變為黃燈,再隔一會兒,就會變成紅燈,如此不斷反覆。

  21. FUNCTIONS AND DESIGNS OF PROTOCOLS • We use the Finite State Machine (FSM) • Each vehicle operates under one and only one of the following four states at any given time: • cluster-head (CH) • quasi-cluster-head (QCH) • cluster-member (CM) • quasi-cluster-member (QCM)

  22. FUNCTIONS AND DESIGNS OF PROTOCOLS Finite state machine of our proposed scheme. T1 and T2 representTransceiver 1 and Transceiver 2

  23. THE INTRACLUSTER COORDINATION AND COMMUNICATION PROTOCOL Time division in the CRC channel

  24. THE INTRACLUSTER COORDINATION AND COMMUNICATION PROTOCOL Tt = 分時多工時間區段 N= 叢集內群組成員 gap = 平均車間距離 v = 平均車輛長度 Lc = 半徑 Nlane = 位於公路上的車道數量

  25. THE INTRACLUSTER COORDINATION AND COMMUNICATION PROTOCOL T=repetition period(重複期間,預設為200ms) R=channel rate Tsafety = 更新安全訊息的間隔時間 Hsafety = 安全訊息的packet size,預設為200bytes

  26. SIMULATION EVALUATIONS • 實驗情境設定 • 環境:單向3線道 • 進入時間:2100秒,變異數:180秒 • 平均速率:35m/s,變異數:15m2 / s2

  27. SIMULATION EVALUATIONS • 實驗工具:Matlab • 參數設定: • 車距:25m • 車長:5m • 車內半徑:150m • 車間半徑:400ms • 接收時間:150ms • 發送時間:50ms • 安全訊息封包大小:200bytes

  28. SIMULATION EVALUATIONS The performance of three protocols against non-real-time trafficarrival rate: a) Probability of safety-message-delivery failure; and b) aggregatethroughput of non-real-time traffics. The size of the non-real-time traffic packetis 512 bytes.

  29. SIMULATION EVALUATIONS Channel busy rates of the seven different channels. The size of thenon-real-time traffic packet is 512 bytes and the packet arrival rate of the nonreal-time traffic is 200packets/sec/vehicle.

  30. CONCLUSIONS • Reducedata-congestion • Support QoS for real-timedelivery of safety messages • High throughput

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