Title:Relay Control for Full-Duplex Relaying with Wireless Information and Energy Transfer

Abstract:This paper investigates the wireless information and energy transfer for the dual-hop amplify-and-forward full-duplex relaying system. By considering the time switching relay transceiver architecture, the full duplex information relaying is powered via the energy harvested from the source-emitted radio frequency signal. The throughput performances of three relay control schemes, namely, the maximum relay gain, the optimal relay gain, and the target relay gain are investigated. The analytical expressions for the outage probability and the ergodic capacity are presented for all the three relay control schemes. The time switching factors for the optimal relay gain and the target relay gain are, respectively, presented in closed-form. The analytical and numerical results show that the optimal relay gain and the target relay gain achieve better outage performances than the maximum relay gain. The optimal relay gain achieves a higher ergodic capacity than that of the maximum relay gain in high signal-to-noise ratios, while the target relay gain achieves a competitive ergodic capacity without requiring the second-hop channel condition. Compared with the maximum relay gain employing the numerically optimized time switching, the competitive throughput performances are achieved by the optimal relay gain and the target relay gain, respectively. It also observes that when the relay is placed in the middle of the source and the destination, the maximum relay gain and the optimal relay gain achieve the relatively worse throughput performance, while the throughput decreases dramatically for the target relay gain when the relay moves from the source towards the destination.