Movable Antenna-Enhanced Near-Field Flexible Beamforming: Performance Analysis and Optimization

TL;DR

This paper explores the use of movable antennas for flexible near-field beamforming, proposing optimization algorithms for position and beamforming design, and analyzing the impact of positioning errors on performance.

Contribution

It introduces novel optimization methods for movable antenna placement and beamforming in near-field scenarios, including practical error analysis.

Findings

Proposed algorithms achieve high-quality solutions for beamforming optimization.

Proper antenna positioning can control beam nulls and gains effectively.

Position errors significantly affect beamforming performance, as analyzed.

Abstract

As an emerging wireless communication technology, movable antennas (MAs) offer the ability to adjust the spatial correlation of steering vectors, enabling more flexible beamforming compared to fixed-position antennas (FPAs). In this paper, we investigate the use of MAs for two typical near-field beamforming scenarios: beam nulling and multi-beam forming. In the first scenario, we aim to jointly optimize the positions of multiple MAs and the beamforming vector to maximize the beam gain toward a desired direction while nulling interference toward multiple undesired directions. In the second scenario, the objective is to maximize the minimum beam gain among all the above directions. However, both problems are non-convex and challenging to solve optimally. To gain insights, we first analyze several special cases and show that, with proper positioning of the MAs, directing the beam toward a specific direction can lead to nulls or full gains in other directions in the two scenarios, respectively. For the general cases, we propose a discrete sampling method and an alternating optimization algorithm to obtain high-quality suboptimal solutions to the two formulated problems. Furthermore, considering the practical limitations in antenna positioning accuracy, we analyze the impact of position errors on the performance of the optimized beamforming and MA positions, by introducing a Taylor series approximation for the near-field beam gain at each target. Numerical results validate our theoretical findings and demonstrate the effectiveness of our proposed algorithms.