Research Article
Power Beacons Deployment in Wireless Powered Communication with Truncated Poisson Cluster Process
@INPROCEEDINGS{10.1007/978-3-030-32388-2_29, author={Siyuan Zhou and Jinhang Zhao and Guoping Tan and Xujie Li and Qin Yan}, title={Power Beacons Deployment in Wireless Powered Communication with Truncated Poisson Cluster Process}, proceedings={Machine Learning and Intelligent Communications. 4th International Conference, MLICOM 2019, Nanjing, China, August 24--25, 2019, Proceedings}, proceedings_a={MLICOM}, year={2019}, month={10}, keywords={Wireless powered communication (WPC) Power beacons (PBs) Doubly-near-far problem Poisson cluster process (PCP) SNR outage probability}, doi={10.1007/978-3-030-32388-2_29} }
- Siyuan Zhou
Jinhang Zhao
Guoping Tan
Xujie Li
Qin Yan
Year: 2019
Power Beacons Deployment in Wireless Powered Communication with Truncated Poisson Cluster Process
MLICOM
Springer
DOI: 10.1007/978-3-030-32388-2_29
Abstract
Wireless powered communication (WPC) is able to provide the wireless devices (WDs) practically infinite energy for information transmission, by deploying multiple power beacons (PBs) as dedicated energy source. The performance of wireless energy transfer and wireless information transmission may significantly vary depending on the locations of the wireless nodes and the channels used for signal transmission. To enable efficient transmission and overcome the doubly-near-far problem in WPC, this paper proposes a PB deployment strategy where the distribution of PBs is subject to a truncated Poisson cluster process (PCP), and analytically investigates the performance of WPC in terms of the SNR outage probability. Specifically, we consider a harvest-then-transmit communication network, where WDs use RF harvested energy for the information transmission in each time block. The wireless energy transfer between WDs and PBs is achieved by either directed mode (WD is served by the closed PB) or isotropic mode (WD is served by multiple PBs). We first investigate the distribution of the distance between WD and an arbitrary PB in the associated cluster. Then, we derive a numerically computable form of the SNR outage probability for directed mode and a tight upper bound of the SNR outage probability for isotropic mode. Finally, numerical results verify the accuracy of the analytical results, present performance comparisons with varied network parameters, and reveal the advantages of the truncated PCP based PB deployment over the random PB deployment and the symmetric PB deployment.