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Understanding Spatio-Temporal Uncertainty in Medium Access with ALOHA Protocols

Understanding Spatio-Temporal Uncertainty in Medium Access with ALOHA Protocols. Affan Syed, Wei Ye, Bhaskar Krishnamachari, and John Heidemann ACM Proceedings of the second workshop on Underwater networks (WuWNet 2007). Outline. Introduction Spatio-Temporal Uncertainty

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Understanding Spatio-Temporal Uncertainty in Medium Access with ALOHA Protocols

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  1. Understanding Spatio-TemporalUncertainty in Medium Access with ALOHA Protocols Affan Syed, Wei Ye, Bhaskar Krishnamachari, and John Heidemann ACM Proceedings of the second workshop on Underwater networks (WuWNet 2007)

  2. Outline • Introduction • Spatio-Temporal Uncertainty • Understanding With ALOHA • Handling Space Uncertainty • Future Work • Conclusion

  3. Introduction • Underwater sensor network become an important area of research • Space-time Uncertainty, defined as the two dimensional uncertainty • packet transmit time • propagation latency

  4. Space-Time Uncertainty Same Transmission Time Different Transmission Time no collision

  5. Evaluation Methodology • ALOHA protocols are the simplest and earliest wireless MAC protocols • It consists of a single receiver that does not transmit • nodes randomly deployed in a circular region

  6. vulnerability interval vulnerability interval 2T Data Data T T T ALOHA with Time Uncertainty Slotted ALOHA Pure ALOHA

  7. Classical Throughput Analysis

  8. ALOHA with Space Uncertainty • Simple ALOHA-constant delay max propagation delay / transmit time

  9. ALOHA with Space Uncertainty • Slotted ALOHA – any propagation latency

  10. ALOHA with Space Uncertainty • Slotted ALOHA – any propagation latency

  11. Slotted ALOHA with Guard Bands β= 1 βtmax A Data farthest A’s Data R

  12. Choosing β • β= 1, no overlap at the receiver unless packets send at same time • increase packet transmission latency and bandwidth overhead • β< 1, some node pair remains overlap • lowers band width overhead, increases collision probability • tradeoff

  13. Parameters β (1)

  14. Parameters β (2)

  15. Analysis with Guard Bands • Throughput • Assume a > 0 and βa ≦1 • expected number of collision-free packets per slot is independent of a each transmits a packet in a given slot

  16. Varying Guard Bands Length

  17. Varying Maximum Delay

  18. Simple ALOHA with Guard Bands

  19. Future Work • Plan to rigorously analyze the throughput capacity • removing the assumption regarding single and equidistant receiver • Provide a framework to analyze other wireless protocols • CSMA • increase understanding of the characteristics of MAC in UWSN.

  20. Conclusion • While designing MAC protocols under high latency environment • it is necessary to consider both space and time uncertainty • Smaller ratio of propagation delay to packet length result get better • short-range communication

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