Threshold-Based Pair Switching Scheme in SWIPT-Enabled Wireless Downlink System

In this paper, we investigate a low complexity technique for simultaneous wireless information and power transfer (SWIPT) in the context of cellular networks, where the  multiple-antenna user equipments (UEs) employ maximum ratio combining technique. In particular, our proposed technique allocates a subset of antennas for information decoding (ID),  only when their post-combiner signal-to-interference ratio exceeds a certain threshold, while the remaining antennas are allocated for energy harvesting (EH). In contrast to conventional approaches, where an uncorrelated or a fully correlated interference is considered,  we develop a realistic mathematical framework that accurately captures the interference correlation effects on the performance of the proposed technique.  By using stochastic geometry tools,  we derive analytical expressions for both the ID and EH success probability, as well as the joint ID and EH success probability.  Our results demonstrate the impact of spatial interference correlation on both the ID and the EH success probability, and we establish the optimal threshold for the proposed antenna switching scheme, that maximizes the joint ID and EH success probability.