Joint Spatial Division and Multiplexing for mm-Wave Channels

TL;DR

This paper evaluates the performance of the JSDM algorithm in mm-Wave Massive MIMO systems, considering realistic channel conditions and proposing low-complexity variants that maintain high efficiency.

Contribution

It introduces a graph-theoretic user grouping framework, greedy algorithms for optimization, and a low-complexity JSDM variant requiring only average CSI.

Findings

Low-complexity JSDM performs well in realistic channels.

Different algorithms excel under different conditions.

Proposed methods reduce feedback and computational overhead.

Abstract

Massive MIMO systems are well-suited for mm-Wave communications, as large arrays can be built with reasonable form factors, and the high array gains enable reasonable coverage even for outdoor communications. One of the main obstacles for using such systems in frequency-division duplex mode, namely the high overhead for the feedback of channel state information (CSI) to the transmitter, can be mitigated by the recently proposed JSDM (Joint Spatial Division and Multiplexing) algorithm. In this paper we analyze the performance of this algorithm in some realistic propagation channels that take into account the partial overlap of the angular spectra from different users, as well as the sparsity of mm-Wave channels. We formulate the problem of user grouping for two different objectives, namely maximizing spatial multiplexing, and maximizing total received power, in a graph-theoretic framework. As the resulting problems are numerically difficult, we proposed (sub optimum) greedy algorithms as efficient solution methods. Numerical examples show that the different algorithms may be superior in different settings.We furthermore develop a new, "degenerate" version of JSDM that only requires average CSI at the transmitter, and thus greatly reduces the computational burden. Evaluations in propagation channels obtained from ray tracing results, as well as in measured outdoor channels show that this low-complexity version performs surprisingly well in mm-Wave channels.