Pinching-Antenna Systems-Assisted SWIPT: A Rate-Energy Trade-off Perspective

TL;DR

This paper explores the rate-energy trade-off in pinching-antenna systems (PASS) for SWIPT, proposing optimization algorithms for single and multiple user scenarios, and demonstrating superior performance over conventional systems.

Contribution

It introduces novel beamforming and resource allocation algorithms for PASS-assisted SWIPT, addressing both single and multiple user scenarios with multiple access schemes.

Findings

PASS achieves a larger rate-energy region than conventional systems.

TDMA outperforms NOMA and FDMA in multiple user scenarios.

Proposed algorithms effectively optimize the rate-energy trade-off.

Abstract

This paper investigates the rate-energy trade-off for pinching-antenna systems (PASS)-assisted simultaneous wireless information and power transfer (SWIPT) systems. Both the single information user (IU)/energy user (EU) and multiple IUs/EUs scenarios are considered.1) For the single IU/EU scenario, a pinching beamforming optimization problem is formulated for simultaneously maximizing data rate and harvested energy. To tackle this problem, a two-stage algorithm is proposed. Specifically, the successive convex approximation (SCA) method is first invoked for minimizing the large-scale path loss, which is followed by the fine-tuning method for the phase alignment. 2) For the multiple IUs/EUs scenario, three multiple access schemes are considered, i.e., frequency division multiple access (FDMA), time division multiple access (TDMA), and non-orthogonal multiple access (NOMA). The corresponding multi-objective optimization problem (MOOP) that simultaneously maximizes the minimum data rate and minimum harvested energy is formulated for ensuring users' fairness. To address this problem, we adopt the $\epsilon$-constraint method to first convert the intractable MOOPs to single-objective optimization problems (SOOPs). Then, for the SOOP under each multiple access protocol, the particle swarm optimization (PSO) and convex optimization methods are adopted for solving the pinching beamforming and resource allocation problems, respectively. Simulation results unveil that: i) PASS can achieve a significantly superior rate-energy region compared to conventional fixed-position antenna systems for pinching beamforming; and ii) by exploiting the time-switching feature, TDMA can outperform both NOMA and FDMA for the multiple IUs/EUs scenario.