Proactive coverage method for monitoring target flow in wireless sensor networks

被引：0

作者：

Wen J. ^{[1
]}

Dou Q. ^{[1
]}

Jiang J. ^{[1
]}

Qi X.-Y. ^{[1
]}

Dou W.-H. ^{[1
]}

机构：

[1] School of Computer, National University of Defense Technology

来源：

Ruan Jian Xue Bao/Journal of Software | 2010年 / 21卷 / 08期

关键词：

Arrive interval; Poisson distribution; Proactive coverage; Static coverage; Target flow;

D O I：

10.3724/SP.J.1001.2010.03590

中图分类号：

学科分类号：

摘要：

This paper presents a time-variant coverage mechanism, proactive coverage. In proactive coverage, all sensor nodes work in lower power surveillance manner which can detect target intrusion with high probability to save energy when the target flow doesn't arrive. As soon as the target flow arrives, sensor nodes are awakened to build a local high quality coverage networks to sense intervening targets. When target flow leaves the target field, sensor nodes converge to a quiet surveillance state. Proactive coverage is more energy efficient than static area coverage, higher sensing quality than event-driven coverage. This paper analyzes preliminary problems in proactive coverage and finds theoretic results on initial detecting delay, awaking nodes strategy and active sensing duration. Numeric results from simulation reveal that initial detecting delay in proactive coverage is trivial. Compared with static area coverage, this coverage mechanism for an adequate scale target flow (above 30 targets) can prolong the network's lifetime to near 4~7 times. © by Institute of Software, the Chinese Academy of Sciences. All rights reserved.

引用

页码：1982 / 1997

页数：15

共 25 条

[1] Akyildiz I.F., Su W.L., Sankarasubramaniam Y., Cayirci E., A survey on sensor networks, IEEE Communications Magazine, 40, 8, pp. 101-114, (2002)
[2] Ren F.Y., Huang H.N., Lin C., Wireless sensor networks, Journal of Software, 14, 7, pp. 1282-1291, (2003)
[3] Ren Y., Zhang S.D., Zhang H.K., Theories and algorithms of coverage control for wireless sensor networks, Journal of Software, 17, 3, pp. 422-433, (2006)
[4] Gui C., Mohapatra P., Power conservation and quality of surveillance in target tracking sensor networks, Proc. of the 10th Annual Int'l Conf. on Mobile Computing and Networking, (2004)
[5] He T., Vicaire P., Yan T., Luo L.Q., Gu L., Zhou G., Stoleru R., Cao Q., Stankovic J.A., Abdelzaher T., Achieving real-time target tracking using wireless sensor networks, Proc. of the 12th IEEE Real-Time and Embedded Technology and Applications Symp., pp. 37-48, (2006)
[6] Juang P., Oki H., Wang Y., Martonosi M., Peh L.S., Rubenstein D., Energy-Efficient computing for wildlife tracking: Design tradeoffs and early experiences with ZebraNet, ACM SIGARCH Computer Architecture News, 37, 10, pp. 96-107, (2002)
[7] Hoogendoorn S.P., Bovy P.H.L., State-of-the-Art of vehicular traffic flow modeling, Journal of Systems and Control Engineering, 215, 4, pp. 283-303, (2001)
[8] Slijepcevic S., Potkonjak M., Power efficient organization of wireless sensor networks, Proc. of the IEEE Int'l Conf. on Communications (ICC), pp. 472-476, (2001)
[9] Berman P., Calinescu G., Shah C., Zelikovsky A., Power efficient monitoring management in sensor networks, Proc. of the Conf. on IEEE Wireless Communication and Networking, pp. 2329-2334, (2004)
[10] Bai X.L., Yun Z.Q., Xuan D., Lai T.H., Jia W.J., Deploying four-connectivity and full-coverage wireless sensor networks, Proc. of the IEEE Int'l Conf. on Computer Communications (INFOCOM), pp. 296-300, (2008)

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