A Novel Mode Switching Scheme Utilizing Random Beamforming for Opportunistic Energy Harvesting

TL;DR

This paper introduces a novel mode switching scheme using random beamforming in MISO SWIPT networks, enhancing energy harvesting efficiency and rate-energy trade-offs without requiring transmitter CSI.

Contribution

It proposes a new receiver mode switching scheme utilizing random beamforming at the transmitter, improving energy harvesting and information transfer in SWIPT systems with limited CSI.

Findings

Single random beam is asymptotically optimal at high transmit power.

Proposed scheme outperforms periodic switching in energy-rate trade-offs.

Effective in both AWGN and fading channels.

Abstract

Since radio signals carry both energy and information at the same time, a unified study on simultaneous wireless information and power transfer (SWIPT) has recently drawn a significant attention for achieving wireless powered communication networks. In this paper, we study a multiple-input single-output (MISO) multicast SWIPT network with one multi-antenna transmitter sending common information to multiple single-antenna receivers simultaneously along with opportunistic wireless energy harvesting at each receiver. From the practical consideration, we assume that the channel state information (CSI) is only known at each respective receiver but is unavailable at the transmitter. We propose a novel receiver mode switching scheme for SWIPT based on a new application of the conventional random beamforming technique at the multi-antenna transmitter, which generates artificial channel fading to enable more efficient energy harvesting at each receiver when the received power exceeds a certain threshold. For the proposed scheme, we investigate the achievable information rate, harvested average power and/or power outage probability, as well as their various trade-offs in both AWGN and quasi-static fading channels. Compared to a reference scheme of periodic receiver mode switching without random transmit beamforming, the proposed scheme is shown to be able to achieve better rate-energy trade-offs when the harvested energy target is sufficiently large. Particularly, it is revealed that employing one single random beam for the proposed scheme is asymptotically optimal as the transmit power increases to infinity, and also performs the best with finite transmit power for the high harvested energy regime of most practical interests, thus leading to an appealing low-complexity implementation. Finally, we compare the rate-energy performances of the proposed scheme with different random beam designs.