DocumentCode
38994
Title
Energy Provisioning in Wireless Rechargeable Sensor Networks
Author
Shibo He ; Jiming Chen ; Fachang Jiang ; Yau, David K. Y. ; Guoliang Xing ; Youxian Sun
Author_Institution
Dept. of Control Sci. & Eng., Zhejiang Univ., Hangzhou, China
Volume
12
Issue
10
fYear
2013
fDate
Oct. 2013
Firstpage
1931
Lastpage
1942
Abstract
Wireless rechargeable sensor networks (WRSNs) have emerged as an alternative to solving the challenges of size and operation time posed by traditional battery-powered systems. In this paper, we study a WRSN built from the industrial wireless identification and sensing platform (WISP) and commercial off-the-shelf RFID readers. The paper-thin WISP tags serve as sensors and can harvest energy from RF signals transmitted by the readers. This kind of WRSNs is highly desirable for indoor sensing and activity recognition and is gaining attention in the research community. One fundamental question in WRSN design is how to deploy readers in a network to ensure that the WISP tags can harvest sufficient energy for continuous operation. We refer to this issue as the energy provisioning problem. Based on a practical wireless recharge model supported by experimental data, we investigate two forms of the problem: point provisioning and path provisioning. Point provisioning uses the least number of readers to ensure that a static tag placed in any position of the network will receive a sufficient recharge rate for sustained operation. Path provisioning exploits the potential mobility of tags (e.g., those carried by human users) to further reduce the number of readers necessary: mobile tags can harvest excess energy in power-rich regions and store it for later use in power-deficient regions. Our analysis shows that our deployment methods, by exploiting the physical characteristics of wireless recharging, can greatly reduce the number of readers compared with those assuming traditional coverage models.
Keywords
energy harvesting; indoor radio; object recognition; radiofrequency identification; secondary cells; sensor placement; wireless sensor networks; RF signal transmission; WISP tags; WRSN; activity recognition; battery powered system; commercial off-the-shelf RFID reader; energy harvesting; energy provisioning problem; indoor sensor; path provisioning problem; point provisioning problem; sensor deployment; static tag; wireless identification and sensing platform; wireless recharge model; wireless rechargeable sensor network; Antennas; Mathematical model; RF signals; Radiofrequency identification; Wireless communication; Wireless sensor networks; Antennas; Mathematical model; RF signals; Radiofrequency identification; WISP; Wireless communication; Wireless recharging; Wireless sensor networks; energy provisioning; sensor networks;
fLanguage
English
Journal_Title
Mobile Computing, IEEE Transactions on
Publisher
ieee
ISSN
1536-1233
Type
jour
DOI
10.1109/TMC.2012.161
Filename
6295618
Link To Document