Joint Spatial Division and Diversity for Massive MIMO Systems

TL;DR

This paper introduces a novel joint spatial division and diversity scheme for massive MIMO systems that combines pre-beamforming with OSTBC, optimizing performance with partial CSI and various power constraints.

Contribution

It proposes a new beamforming scheme integrating spatial division and OSTBC, along with efficient optimization algorithms for partial CSI scenarios in massive MIMO.

Findings

The proposed JSDD scheme outperforms existing methods in simulations.

Efficient algorithms achieve near-optimal performance under different power constraints.

Closed-form solutions are derived for specific cases.

Abstract

We propose a downlink beamforming scheme that combines spatial division and orthogonal space-time block coding (OSTBC) in multi-user massive MIMO systems. The beamformer is divided into two parts: a pre-beamforming matrix to separate the users into different beams with no interference between each other, which is designed based on the low rank covariance matrix of the downlink channel, and a linear precoding matrix using partial or even no channel state information (CSI) concatenated by an OSTBC. To construct the pre-beamforming matrix, a simple method that selects columns from DFT matrix is presented. To design the linear precoding matrix with partial CSI of the effective channel after the pre-beamforming, we solve an optimization problem to minimize the pairwise error probability (PEP) of the users under an individual power or sum power constraint, respectively. For the individual power constraint, a semi-definite relaxing (SDR) method with a sufficient condition achieving the globally optimal solution is proposed to provide a performance benchmark. In addition, an efficient iterative successive convex approximation (SCA) method is provided to achieve a suboptimal solution. Furthermore, closed form solutions are derived under some special cases. For the sum power constraint, we consider two different designs, i.e., minimizing the average PEP and minimizing the maximum PEP of all users. We find that both non-convex problems have a similar structure, and proposed a unified SCA-Alternating Direction Method of Multipliers (ADMM) algorithm to handle them. The SCA-ADMM method can be implemented in a parallel manner, and thus is with great efficiency. Simulation results show the efficiency of our proposed JSDD scheme and the optimization method.