WSEAS Transactions on Communications


Print ISSN: 1109-2742
E-ISSN: 2224-2864

Volume 16, 2017

Notice: As of 2014 and for the forthcoming years, the publication frequency/periodicity of WSEAS Journals is adapted to the 'continuously updated' model. What this means is that instead of being separated into issues, new papers will be added on a continuous basis, allowing a more regular flow and shorter publication times. The papers will appear in reverse order, therefore the most recent one will be on top.



An Efficient Energy Scheme of Wireless Sensor Node Dynamic Deployment

AUTHORS: Cheng-Chih Yang, Hsuan-Fu Wang, Yung-Fa Huang

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ABSTRACT: This text provides an efficient energy scheme of wireless sensor node dynamic deployment. A single sensor node communication model is defined initial. Sensors are co-working with their neighbors in their transmitting range. Suitable neighbor node number and sensing radius make sensors field more efficient. A value CAPR is defined in this text for power efficiency discriminating. A self-regulated sensing radius mechanism is proposed here that sensor can adjust its radius of sensing range for high efficient energy working.

KEYWORDS: wireless sensor node, coverage area, neighbor node numbers, CAPR, self-regulated mechanism

REFERENCES:

[1] F. Akyildiz, S. Y. Sankarasubramaniam, and E. Cyirci, “Wireless Sensor Networks: A Survey,” Computer Networks, Vol. 38, No. 4, pp. 393-422. , 2002

[2] A. Howard, M. J. Mataric and G. S. Sukhatme, “Mobile Sensor Network Deployment Using Potential Fields: A Distributed, Scalable Solution to the Area Coverage Problem,” In Proceedings of 6th Int. Conf. Distributed Autonomous Robotic System, Fukuoka, Japan, pp. 299-308, 2002.

[3] N. Thangadurai, R. Dhanasekaran and R. D. Karthika, “Dynamic Energy Efficient Topology for Wireless Ad hoc Sensor Networks,” WSEAS Transactions on Communications, Vol. 12, Issue 12, pp. 651-660, December 2013.

[4] D. G. Costa, L. A. Guedes, F. Vasques and P. Portugal, “Redundancy-Based Semi-Reliable Packet Transmission in Wireless Visual Sensor Networks Exploiting the Sensing Relevancies of Source Nodes,” WSEAS Transactions on Communications, Vol. 12, Issue 9, pp. 468-478, September 2013.

[5] Y. Zou and K. Chakrabarty, “Sensor Deployment and Target Localization Based on Virtual Forces,” In Proceedings of IEEE INFOCOM; pp. 1293– 1303, 2003.

[6] J. Li, B. Zhang, L. Cui, and S. Chai, “An Extended Virtual Force-based Approach to Distributed SelfDeployment in Mobile Sensor Networks,” International Journal of Distributed Sensor Networks, 2012.

[7] N. Heo and V. P. Kumar, “A distributed self spreading algorithm for mobile wireless sensor networks,” In Proceedings of IEEE WCNC , pp. 1597 – 1602, 2003.

[8] J. Wen, C. Yan, and Y. Huang, “Performance of Hybrid Virtual Force Algorithms on Mobile Deployment in Wireless Sensor Networks,” WSEAS Transactions on Communications, Art. #61, Volume 13, pp. 558-566, 2014.

[9] J. Liu, and B. Li, “Mobilegrid: Capacity-Aware Topology Control in Mobile Ad Hoc Networks,” In Proceedings of IEEE International Conference on Computer Communications and Networks, pp. 570– 574, 2002.

WSEAS Transactions on Communications, ISSN / E-ISSN: 1109-2742 / 2224-2864, Volume 16, 2017, Art. #38, pp. 342-346


Copyright © 2017 Author(s) retain the copyright of this article. This article is published under the terms of the Creative Commons Attribution License 4.0

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