Chenyang XIA, Kezhang LIN, Jun CHEN, Yang ZHANG, Yuling LIU

Path planning and energy flow control of wireless power transfer for sensor nodes in wireless sensor networks

In wireless sensor networks (WSNs), limited-capacity batteries are generally used for powering sensor nodes,where unbalanced electricity is the primary cause of premature death of WSNs. In this paper, wireless power transfernetworks are used to power batteries in WSNs to avoid the problem of limited lifetime of traditional limited-capacitybatteries. Furthermore, path planning based on the Dijkstra algorithm, which aims at minimizing the overall energyconsumption in the network to improve system efficiency, is discussed in detail. Finally, three power transfer modelswith low contention level (LCL) topology for energy flow control are experimentally validated from the optimal path

PDF

___

Akyildiz IF, Su W, Sankarasubramaniam Y, Cayirci E. Wireless sensor networks: a survey. Comput Netw 2002; 38: 393-422.
Peng CH, Qian K, Wang CY. Design and application of a VOC-monitoring system based on a ZigBee wireless sensor network. IEEE Sens J 2017; 17: 2255-2268.
Asaduzzaman, Kong HY. Energy efficient cooperative LEACH protocol for wireless sensor networks. J Commun Netw 2010; 12: 358-365.
Younis O, Fahmy S. HEED: a hybrid, energy-efficient, distributed clustering approach for ad hoc sensor networks. IEEE T Mobile Comput 2004; 3: 366-379.
Yan JJ, Zhou MC, Ding ZJ. Recent advances in energy-efficient routing protocols for wireless sensor networks: a review. IEEE Access 2016; 4: 5673-5686.
Zhao M, Yang YY. Optimization-based distributed algorithms for mobile data gathering in wireless sensor networks. IEEE T Mobile Comput 2012; 11: 1464-1477.
Wang C, Li J, Ye F, Yang YY. A mobile data gathering framework for wireless rechargeable sensor networks with vehicle movement costs and capacity constraints. IEEE T Comput 2016; 65: 2411-2427.
Elliott GAJ, Raabe S, Covic GA, Boys JT. Multiphase pickups for large lateral tolerance contactless power transfer systems. IEEE T Ind Electron 2010; 57: 1590-1598.
Liu X, Hui SY. Optimal design of a hybrid winding structure for planar contactless battery charging platform. IEEE T Power Electr 2008; 23: 455-463.
Zhou SJ, Mi CC. Multi-paralleled LCC reactive power compensation networks and their tuning method for electric vehicle dynamic wireless charging. IEEE T Ind Electron 2016; 63: 6546-6556.
Lee CH. Wireless information and power transfer for communication recovery in disaster areas. In: 2014 IEEE 15th International Symposium On a World of Wireless, Mobile and Multimedia Networks (WOWMOM); 16–19 June 2014; Sydney, Australia: IEEE. pp. 235-239.
Li TS, Han Z, Ogai H, Sawada K, Wang J. A microchip-controlling wireless power transfer system for sensor network. In: 2012 SCIE Annual Conference; 20–23 August 2012; Akita University, Akita, Japan: IEEE. pp. 337-341.
Zhao M, Li J, Yang YY. A framework of joint mobile energy replenishment and data gathering in wireless rechargeable sensor networks. IEEE T Mobile Comput 2014; 13: 2689-2705.
He SB, Chen JM, Jiang FC, Yau DKY, Xing GL, Sun YX. Energy provisioning in wireless rechargeable sensor networks. IEEE T Mobile Comput 2013; 12: 1931-1942.
Yan JJ, Zhou MC, Ding ZJ. Effects of practical recharge ability constraints on perpetual RF harvesting sensor network operation. IEEE Access 2016; 4: 750-765.
Dijkstra EW. A note on two problems in connexion with graphs. J Numer Math 1959; 1: 269-271.