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Radio-Triggered Wake-Up for Wireless Sensor Networks

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Abstract

Power management is an important technique to prolong the lifespan of sensor networks. Many power management protocols employ wake-up/sleep schedules, which are often complicated and inefficient. We present power management schemes that eliminate such wake-up periods unless the node indeed needs to wake up. This type of wake-up capability is enabled by a new radio-triggered hardware component inspired by the observation that the wake-up radio signal contains enough energy to trigger a wake-up process. We evaluate the potential power saving in terms of the lifespan of a sensor network application, using experimental data and SPICE circuit simulations. Comparing the result with always-on and rotation-based power management schemes, we find the radio-triggered scheme saves 98% of the energy used in the always-on scheme, and saves over 70% of the energy used in the rotation-based scheme. Consequently, the lifespan increases from 3.3 days (always-on) or 49.5 days (rotation-based) to 178 days (radio-triggered). Furthermore, a store-energy technique can extend operating distance from 10 feet to 22 feet, or even longer if longer latency is acceptable. Wake-up efficiency is evaluated in NS-2 simulations, which show that radio-triggered wake-up has fewer failures, shorter latency, and consistently larger sensing laxity than rotation based wake-up. We also present amplification and radio-triggered IDs which can further enhance performance.

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Authors and Affiliations

  1. Department of Computer Science, University of Virginia, Virginia

    Lin Gu & John A. Stankovic

Authors
  1. Lin Gu
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  2. John A. Stankovic
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Correspondence to Lin Gu.

Additional information

Lin Gu is a Ph.D. student at University of Virginia. His current research area is in wireless sensor networks, focusing on OS kernel services and energy efficient hardware and architecture support. Before joining to UVa, he got M.S. degree from Peking University and B.S. in Computer Science from Fudan University.

John A. Stankovic is the BP America Professor in the Computer Science Department at the University of Virginia. He recently served as Chair of the department, completing two terms. He is a Fellow of both the IEEE and the ACM. He also won the IEEE Real-Time Systems Technical Committee’s Award for Outstanding Technical Contributions and Leadership. Professor Stankovic also serves on the Board of Directors of the Computer Research Association. Before joining the University of Virginia, Professor Stankovic taught at the University of Massachusetts where he won an outstanding scholar award. He has also held visiting positions in the Computer Science Department

at Carnegie-Mellon University, at INRIA in France, and Scuola Superiore S. Anna in Pisa, Italy. He was the Editor-in-Chief for the IEEE Transactions on Distributed and Parallel Systems and is a co-editor-in-chief for the Real-Time Systems Journal. His research interests are in distributed computing, real-time systems, operating systems, and wireless sensor networks. Prof. Stankovic received his Ph.D. from Brown University.

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Gu, L., Stankovic, J.A. Radio-Triggered Wake-Up for Wireless Sensor Networks. Real-Time Syst 29, 157–182 (2005). https://doi.org/10.1007/s11241-005-6883-z

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  • DOI: https://doi.org/10.1007/s11241-005-6883-z

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