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MAC Protocols for Sensor Networks

MAC Protocols for Sensor Networks. Paper Presentation of selected topics in EE206A Based on the work of Alec Woo, David Culler, Wei Ye, Join Heidemann, and Deborah Estrin Slides by Dayou Qian and Xiaolong Huang. Outline. The characteristics of sensor networks

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MAC Protocols for Sensor Networks

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  1. MAC Protocols for Sensor Networks Paper Presentation of selected topics in EE206A Based on the work of Alec Woo, David Culler, Wei Ye, Join Heidemann, and Deborah Estrin Slides by Dayou Qian and Xiaolong Huang

  2. Outline • The characteristics of sensor networks • Issues of MAC protocols for sensor networks • Proposed solutions for MAC protocols • An adaptive rate control scheme • S-MAC (Sensor-MAC) • Bibliography

  3. The characteristics of sensor networks • Tight constraints • Computation power • Storage • Primary functions • Sample the environment for sensory information • Propagate data back to the infrastructure • Traffic pattern • Little activity in lengthy period • Intensive traffic in short time • Highly correlated traffic • End to end flows are required to be fair Base station Sensor Multihop

  4. The characteristics of sensor networks • Networking component stack for sensor networks Complete TinyOS application component graph

  5. Issues in MAC protocols for sensor networks • Issues • Energy efficiency • Fairness of end to end flows • Related work • IEEE802.11 • High energy consumption when the nodes are in the idle mode • CSMA • To improve the energy consumption by avoiding overhearing among neighboring nodes • TDMA • No contention-introduced overhead and collisions • Not easy to manage the inter-cluster communication and interference • Not easy to dynamically change its frame length and time slot assignment • PAMAS • Power off radio when not actively transmitting and receiving packet

  6. An adaptive rate control scheme • The metrics for evaluation of a sensor network MAC protocol • Fair bandwidth allocation from each node to the base station over multihops is desired. • Energy efficiency is desired, including energy spent in listening for the channel and all packets transmissions and forwarding. • Design

  7. An adaptive rate control scheme • Rate control mechanism • Monitor route through traffic and original traffic • Application data rate , Probability of transmission , actual data originate rate • Increment by a constant , when application traffic is congested • Monitor: • Multiply by a factor , when application traffic is not congested • Monitor: , because dropping route through traffic is more expensive • Hidden terminal problem solved by parenting • If a node hears its parent transmit at time , assume its grandparent will start at time • The node restrains from transmission from time to

  8. An adaptive rate control scheme • Simulation settings • Various CSMA schemes with different settings on: random delay, listening time, backoff scheme • Single cell topology • Small data packets 30 bytes • CSMA versus IEEE 802.11 • Results on throughput • Randomness improves the throughput performance

  9. An adaptive rate control scheme • Results on energy consumption • IEEE 802.11 is worst in terms of listening energy consumption due to carrier sensing during backoff time • The most efficient schemes are those CSMA with constant listening time and random delay • Results on fairness • Different backoff scheme is insignificant for fairness

  10. An adaptive rate control scheme • Results on application phase shift • Better fairness is provided • Conclusion • CSMA mechanism should incorporate random delay, constant listen period with radio powered down during backoff period

  11. An adaptive rate control scheme • Results on fairness • Fairness is achieved by ARC • Multihop simulation settings • Multihop environment with bidirectional link

  12. An adaptive rate control scheme • Results on energy efficiency • Conclusion • The adaptive rate control scheme together with the new CSMA mechanism provides an effective medium access control without explicit control packets, which is effective in achieving fairness while maintaining good aggregate bandwidth with reasonable energy efficiency

  13. S-MAC (Sensor-Networks) • Trade Off • Energy efficiency Node-level fairness & Latency • Basic Scheme: Periodic Listen and Sleep • Choosing schedule • The node randomly choose a time to go to sleep. • The node receives and follows its neighbor’s schedule by setting its schedule to be the same. • If the node receives a different schedule after it select its own schedule, it adopts both schedules.

  14. S-MAC (Sensor-Networks) • Maintaining Schedule • To update schedule by sending a SYNC packet periodically

  15. S-MAC (Sensor-Networks) • Collision Avoidance • Virtual carrier sense checking the keeping silent time recorded in the NAV (network allocation vector) • Physical carrier sense Listening to the channel for possible transmission • RTS/CTS exchange • Overhearing Avoidance • Let interfering nodes go to sleep after they hear an RTS or CTS packet

  16. S-MAC (Sensor-Networks) • Message passing • Only one RTS packet and one CTS packet are used To avoid large control overhead and long delay • ACK would be sent after each data fragment To avoid fragment loss or error To Prevent hidden terminal problem • After the neighbor node hears the RTS and CTS, it will go to sleep for the time that is needed to transmit all the fragments (using the duration field)

  17. S-MAC (Sensor-Networks) • Energy Saving vs. Increasing latency (Multi-hop Network) • Carrier sense delay Determined by the contention window size • Backoff delay Because the node detects another transmission or the collision occurs • Transmission delay Determined by channel bandwidth, packet length and the coding scheme adopted • Propagation delay Determined by the distance between the sending and receiving nodes • Processing delay Depends on the computing power of the node and the efficiency of in-network data processing algorithms • Queuing delay Depends on the traffic load • Sleep delay Caused by the nodes periodic sleeping

  18. S-MAC (Sensor-Networks) • Testbed • Used Rene Motes as the development platform and testbed • TinyOS • 3 working modes: receiving, transmitting and sleep • Topology used in the experiment • 3 MAC modules on the mote and TinyOS platform • Simplified IEEE802.11 DCF • Message passing with overhearing avoidance • The complete S-MAC

  19. S-MAC (Sensor-Networks) • The energy consumption result on the source nodes A and B • When the traffic is heavy (the inter-arrival time<4s), S-MAC achieves energy saving mainly by avoiding overhearing and efficiently transmitting a long message • When the traffic is light, the periodic sleep plays a key role for energy savings

  20. S-MAC (Sensor-Networks) • The percentage of time that the source nodes are in the sleep mode • The S-MAC protocol adjusts the sleep time according to the traffic patterns • The Module of message passing with overhearing avoidance spend more and more time in idle listening when the traffic is light

  21. S-MAC (Sensor-Networks) • Energy consumption in the intermediate nodes • When the traffic is light, S-MAC still outperforms 802.11 MAC Reason1:S-MAC has synchronization overhead of sending and receiving SYNC packets Reason2:S-MAC introduces more latency and actually uses more time to transmit the same amount of data

  22. S-MAC (Sensor-Networks) • Conclusion • This new MAC protocol has very good energy conserving compared with IEEE802.11. • This new MAC protocol has the ability to make trade-offs between energy and latency according to the traffic conditions.

  23. Bibliography • The contents of the slides are based on • Alec Woo and David Culler. A transmission control scheme for medium access in sensor networks. Mobicom 2001 • Wei Ye, Join Heidemann, and Deborah Estrin. A energy-efficient MAC protocol for wireless sensor networks. Infocom 2002

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