Multiuser Communications Aided by Cross-Linked Movable Antenna Array: Architecture and Optimization

TL;DR

This paper introduces a cross-linked movable antenna array architecture that reduces hardware costs and optimizes antenna positioning to enhance multiuser uplink communication efficiency, achieving near-optimal power minimization with lower movement overhead.

Contribution

The paper proposes a novel cross-linked MA array architecture and develops optimization algorithms for antenna positioning, improving power efficiency and reducing movement overhead in multiuser systems.

Findings

Significant power reduction compared to fixed-position antennas.

Close performance to theoretical lower bounds.

Statistical optimization reduces movement overhead with minimal performance loss.

Abstract

Movable antenna (MA) has been regarded as a promising technology to enhance wireless communication performance by enabling flexible antenna movement. However, the hardware cost of conventional MA systems scales with the number of movable elements due to the need for independently controllable driving components. To reduce hardware cost, we propose in this paper a novel architecture named cross-linked MA (CL-MA) array, which enables the collective movement of multiple antennas in both horizontal and vertical directions. To evaluate the performance benefits of the CL-MA array, we consider an uplink multiuser communication scenario. Specifically, we aim to minimize the total transmit power while satisfying a given minimum rate requirement for each user by jointly optimizing the horizontal and vertical antenna position vectors (APVs), the receive combining at the base station (BS), and the transmit power of users. A globally lower bound on the total transmit power is derived, with closed-form solutions for the APVs obtained under the condition of a single channel path for each user. For the more general case of multiple channel paths, we develop a low-complexity algorithm based on discrete antenna position optimization. Additionally, to further reduce antenna movement overhead, a statistical channel-based antenna position optimization approach is proposed, allowing for unchanged APVs over a long time period. Simulation results demonstrate that the proposed CL-MA schemes significantly outperform conventional fixed-position antenna (FPA) systems and closely approach the theoretical lower bound on the total transmit power. Compared to the instantaneous channel-based CL-MA optimization, the statistical channel-based approach incurs a slight performance loss but achieves significantly lower movement overhead, making it an appealing solution for practical wireless systems.