Joint Sequential Fronthaul Quantization and Hardware Complexity Reduction in Uplink Cell-Free Massive MIMO Networks

TL;DR

This paper proposes a cooperative quantization approach for fronthaul links in uplink cell-free massive MIMO networks, utilizing inter-AP and intra-AP de-correlation to reduce distortion and hardware complexity, leading to improved signal estimation accuracy.

Contribution

It introduces a novel cooperative quantization scheme with pre-processing steps that exploit correlations, enhancing fronthaul efficiency and reducing hardware complexity in massive MIMO networks.

Findings

Inter-AP de-correlation improves quantization efficiency.

Intra-AP de-correlation further reduces distortion.

Proposed method enhances BER and NMSE performance.

Abstract

Fronthaul quantization causes a significant distortion in cell-free massive MIMO networks. Due to the limited capacity of fronthaul links, information exchange among access points (APs) must be quantized significantly. Furthermore, the complexity of the multiplication operation in the base-band processing unit increases with the number of bits of the operands. Thus, quantizing the APs' signal vector reduces the complexity of signal estimation in the base-band processing unit. Most recent works consider the direct quantization of the received signal vectors at each AP without any pre-processing. However, the signal vectors received at different APs are correlated mutually (inter-AP correlation) and also have correlated dimensions (intra-AP correlation). Hence, cooperative quantization of APs fronthaul can help to efficiently use the quantization bits at each AP and further reduce the distortion imposed on the quantized vector at the APs. This paper considers a daisy chain fronthaul and three different processing sequences at each AP. We show that 1) de-correlating the received signal vector at each AP from the corresponding vectors of the previous APs (inter-AP de-correlation) and 2) de-correlating the dimensions of the received signal vector at each AP (intra-AP de-correlation) before quantization helps to use the quantization bits at each AP more efficiently than directly quantizing the received signal vector without any pre-processing and consequently, improves the bit error rate (BER) and normalized mean square error (NMSE) of users signal estimation.