Rotatable Coupler Antenna Enhanced Wireless Network: Modeling and Coupler Rotation Optimization

TL;DR

This paper introduces a rotatable coupler antenna system that enhances wireless communication by optimizing coupler rotations for better spectrum and energy efficiency without additional RF chains.

Contribution

It models a new RCA system with 3D coupler rotations, formulates an optimization problem, and proposes an algorithm to improve wireless performance efficiently.

Findings

Significant SNR improvement over benchmarks

Fewer active antennas and RF chains needed

Effective 3D rotation optimization enhances performance

Abstract

Flexible coupler antenna systems have recently received significant research interest due to their capability to intelligently reconfigure wireless channels by controlling coupler positions and/or rotations and dynamically exploiting mutual coupling. In this paper, we investigate a new type of flexible coupler antenna, termed rotatable coupler antenna (RCA), for enabling spectrum and energy efficient wireless communication cost-effectively. Specifically, an RCA consists of one fixed active antenna and multiple low-cost passive couplers, each of which can independently rotate in three-dimensional (3D) space, so as to collaboratively achieve mechanical beamforming without requiring additional radio-frequency (RF) chains for the couplers. We study an RCA-enhanced point-to-point communication system, where one RCA is deployed at the transmitter to serve a single user equipped with a fixed antenna. Based on multi-port circuit theory, we establish the channel model and characterize the mutual coupling coefficients as a function of coupler rotations. We formulate a new problem to maximize the received signal-to-noise ratio (SNR) at the user by optimizing the 3D rotations of all couplers, subject to practical coupler rotation constraints. To tackle this nonconvex problem, we develop a spherical-cap conditional-gradient-based algorithm with cross-entropy-method initialization. Simulation results demonstrate that the proposed RCA system can significantly improve communication performance in comparison with benchmark schemes, while requiring substantially fewer active antennas and RF chains.