Optimizing ISAC MIMO Systems with Reconfigurable Pixel Antennas

TL;DR

This paper introduces a novel ISAC MIMO system utilizing reconfigurable pixel antennas with EM and digital beamforming, significantly enhancing sensing capabilities and reducing antenna count for future 6G networks.

Contribution

It presents a new EM-aware beamforming architecture with reconfigurable pixel antennas and an optimization framework for joint sensing and communication performance.

Findings

Achieves higher sensing rates than conventional arrays.

Enables antenna reduction while maintaining ISAC performance.

Demonstrates the effectiveness of EM-aware design through simulations.

Abstract

The integration of sensing and communication demands architectures that can flexibly exploit spatial and electromagnetic (EM) degrees of freedom (DoF). This paper proposes an Integrated Sensing and Communication (ISAC) MIMO framework that uses Reconfigurable Pixel Antenna (RPixA), which introduces additional EM-domain DoF that are electronically controlled through binary antenna coder switch networks. We introduce a beamforming architecture combining this EM and digital precoding to jointly optimize Sensing and Communication. Based on full-wave simulation of pixel antenna, we formulate a non-convex joint optimization problem to maximize sensing rate under user-specific constraints on communication rate. We utilize an Alternating Optimization framework incorporating genetic algorithm for port states of Pixel antennas, and semi-definite relaxation (SDR) for digital beamforming. Numerical results demonstrate that the proposed EM-aware design achieves considerably higher sensing rate compared to conventional arrays and enables considerable antenna reduction for equivalent ISAC performance. These findings highlight the potential of reconfigurable pixel antennas to realize efficient and scalable EM-aware ISAC systems for future 6G networks.