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Prediction-based Strategies for Energy Saving in Object Tracking Sensor Networks

2004 IEEE International Conference on Mobile Data Management Yingqi Xu, Julian Winter, Wang-Chien Lee. Prediction-based Strategies for Energy Saving in Object Tracking Sensor Networks. Contents. The direction of designing energy-aware object tracking algorithms

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Prediction-based Strategies for Energy Saving in Object Tracking Sensor Networks

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  1. 2004 IEEE International Conference on Mobile Data Management Yingqi Xu, Julian Winter, Wang-Chien Lee Prediction-based Strategies for Energy Saving in Object Tracking Sensor Networks

  2. Contents • The direction of designing energy-aware object tracking algorithms • A prediction-based energy saving scheme. • An extensive performance evaluation • A sensor node: a logical representation of a set of sensor nodes which collaboratively decide the properties of a moving object. A sensing leader/cluster head in a multi-level sensor network.

  3. Impacting factors Factors impacting the energy consumptions. • Number of moving objects • Reporting frequency • Data precision • Sensor sampling frequency • Higher object speed  higher sampling frequency • Object moving speed • Location models

  4. Object Track problem • Requirements: A sensor network with S sensor nodes is equipped to track O moving objects. Each sampling duration takes X seconds. The application requires the sensor nodes to report the objects location (represented by Sensor ID) every T seconds. • Problem Definition: Given the requirements for the object tracking application, develop energy saving schemes which minimize overall energy consumption of the OTSN under an acceptable missing rate.

  5. Basic scheme • Naïve: all the sensor nodes stays in active mode to monitor their detection areas all the time. • Scheduled Monitoring (SM): all the S nodes will be activated for X second then go to sleep for (T − X) seconds. • Continuous Monitoring (CM): only the sensor node who has the object in its detection area will be activated (stay awake).

  6. Solution space of energy saving schemes

  7. Prediction-based Energy Saving Scheme • How to reduce the missing of objects? • Prediction, Wake up • How to re-locate the missing object? • Recovery

  8. Prediction model • Object movement usually remains constant for a certain period of time. • Direction, speed • Heuristics INSTANT • Assume the moving objects stay in the current speed and direction. • Heuristics AVERAGE • The average of the object movement history. • Comm overhead (the size of history) • Heuristics EXP AVG • Assign weights to the historical stages • Compress the history info, reduce the comm overhead

  9. Wake up mechanisms • Do not expect 100% prediction accuracy. • To accommodate the prediction errors, a set of nodes are woken up. • Heuristic DESTINATION • Only inform the destination node • Heuristic ROUTE • Also include the nodes on the route • Heuristic ALL NBR • Dest + Route + neighbors

  10. Recovery mechanism • All neighbors • Flooding recovery

  11. Simulation • Total energy consumption • Radio, sensing, computing … • Missing rate • Failing to report on time

  12. Workload

  13. Pause time The frequency a moving object changes its state in terms of speed and direction.

  14. Moving speed

  15. Sampling frequency

  16. Q & A

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