Wireless Power Transfer in Cooperative DF Relaying Networks with Log-Normal Fading

TL;DR

This paper analyzes wireless power transfer in indoor cooperative relaying networks with log-normal fading, deriving analytical expressions for outage probability and highlighting the importance of parameter optimization for system performance.

Contribution

It provides the first analytical performance evaluation of energy-harvesting protocols in indoor log-normal fading channels for cooperative relaying systems.

Findings

Optimized energy-harvesting parameters significantly improve performance.

PSR protocol approaches ideal performance with proper tuning.

Increasing source power and energy-harvester efficiency enhances system reliability.

Abstract

Energy-harvesting and wireless power transfer in cooperative relaying networks have recently attracted a considerable amount of research attention. Most of the existing work on this topic however focuses on Rayleigh fading channels which represents outdoor environments. Unlike these studies, in this paper we analyze the performance of wireless power transfer in two-hop decode-and-forward (DF) cooperative relaying systems in indoor channels characterized by log-normal fading. Three well-known energy-harvesting protocols are considered in our evaluations: a) time-switching relaying (TSR), b) power-splitting relaying (PSR) and c) ideal relaying receiver (IRR). The performance is evaluated in terms of the ergodic outage probability for which we derive accurate analytical expressions for the three systems under consideration. Results reveal that careful selection of the energy-harvesting time and power-splitting factors in the TSR- and PSR-based system are important to optimize performance. It is also presented that the optimized PSR system has near-ideal performance and that increasing the source transmit power and/or the energy-harvester efficiency can further improve performance.