Statistically Bounding Detection Latency in Low-Duty-Cycled Sensor Networks

Zhu, Yanmin

doi:10.1155/2012/365421

International Journal of Distributed Sensor Networks

2012

DOI: 10.1155/2012/365421

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Statistically Bounding Detection Latency in Low-Duty-Cycled Sensor Networks

Yanmin Zhu

Abstract: Detecting abnormal events represents an important family of applications for wireless sensor networks. To achieve high performance of event detection, a sensor network should stay active most of the time, which is energy inefficient for battery driven sensor networks. This paper studies the fundamental problem of bounding detection delays when the sensor network is low duty cycled. We propose a novel approach for statistically bounding detection latency for event detection in sensor networks. The key issue is … Show more

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2014

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References 30 publications

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Towards Energy-Fairness in Asynchronous Duty-Cycling Sensor Networks

2014

ACM Trans. Sen. Netw.

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Abstract-In this paper, we investigate the problem of controlling node sleep intervals so as to achieve the min-max energy fairness in asynchronous duty-cycling sensor networks. We propose a mathematical model to describe the energy efficiency of such networks and observe that traditional sleep interval setting strategy, i.e., operating sensor nodes with identical sleep intervals, or intuitive control heuristics, i.e., greedily increasing sleep intervals of sensor nodes with high energy consumption rates, hardly perform well in practice. There is an urgent need to develop an efficient sleep interval control strategy for achieving fair and high energy efficiency. To this end, we theoretically formulate the Sleep Interval Control (SIC) problem and find it a convex optimization problem. By utilizing the convex property, we decompose the original problem and propose a distributed algorithm, called GDSIC. In GDSIC, sensor nodes can tune sleep intervals through a local information exchange such that the maximum energy consumption rate in the network approaches to be minimized. The algorithm is self-adjustable to the traffic load variance and is able to serve as a unified framework for a variety of asynchronous duty-cycling MAC protocols. We implement our approach in a prototype system and test its feasibility and applicability on a 50-node testbed. We further conduct extensive trace-driven simulations to examine the efficiency and scalability of our algorithm with various settings.

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Towards Energy-Fairness in Asynchronous Duty-Cycling Sensor Networks

2014

ACM Trans. Sen. Netw.

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Statistically Bounding Detection Latency in Low-Duty-Cycled Sensor Networks

Cited by 1 publication

References 30 publications

Towards Energy-Fairness in Asynchronous Duty-Cycling Sensor Networks

Towards Energy-Fairness in Asynchronous Duty-Cycling Sensor Networks

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