Message Passing Meets Graph Neural Networks: A New Paradigm for Massive MIMO Systems

TL;DR

This paper introduces AMP-GNN, a novel deep learning framework combining approximate message passing and graph neural networks to enhance massive MIMO system detection, achieving high performance with low complexity and adaptability.

Contribution

It proposes a model-driven deep learning approach that integrates AMP algorithms with GNNs, enabling efficient, adaptable, and robust detection in massive MIMO systems.

Findings

AMP-GNN significantly improves detection performance.

Achieves comparable results to state-of-the-art DL-based detectors.

Demonstrates robustness to system mismatches.

Abstract

As one of the core technologies for 5G systems, massive multiple-input multiple-output (MIMO) introduces dramatic capacity improvements along with very high beamforming and spatial multiplexing gains. When developing efficient physical layer algorithms for massive MIMO systems, message passing is one promising candidate owing to the superior performance. However, as their computational complexity increases dramatically with the problem size, the state-of-the-art message passing algorithms cannot be directly applied to future 6G systems, where an exceedingly large number of antennas are expected to be deployed. To address this issue, we propose a model-driven deep learning (DL) framework, namely the AMP-GNN for massive MIMO transceiver design, by considering the low complexity of the AMP algorithm and adaptability of GNNs. Specifically, the structure of the AMP-GNN network is customized by unfolding the approximate message passing (AMP) algorithm and introducing a graph neural network (GNN) module into it. The permutation equivariance property of AMP-GNN is proved, which enables the AMP-GNN to learn more efficiently and to adapt to different numbers of users. We also reveal the underlying reason why GNNs improve the AMP algorithm from the perspective of expectation propagation, which motivates us to amalgamate various GNNs with different message passing algorithms. In the simulation, we take the massive MIMO detection to exemplify that the proposed AMP-GNN significantly improves the performance of the AMP detector, achieves comparable performance as the state-of-the-art DL-based MIMO detectors, and presents strong robustness to various mismatches.