Base station (BS) architectures for massive multi-user (MU) multiple-input multiple-output (MIMO) wireless systems are equipped with hundreds of antennas to serve tens of users on the same time-frequency channel. The immense number of BS antennas incurs high system costs, power, and interconnect bandwidth. To circumvent these obstacles, sophisticated MU precoding algorithms that enable the use of 1-bit DACs have been proposed. Many of these precoders feature parameters that are, traditionally, tuned manually to optimize their performance. We propose to use deep-learning tools to automatically tune such 1-bit precoders. Specifically, we optimize the biConvex 1-bit PrecOding (C2PO) algorithm using neural networks. Compared to the original C2PO algorithm, our neural-network optimized (NNO-)C2PO achieves the same error-rate performance at $\bf 2\boldsymbol\times$ lower complexity. Moreover, by training NNO-C2PO for different channel models, we show that 1-bit precoding can be made robust to vastly changing propagation conditions.

Publié le : 2019-03-08
Classification:  Computer Science - Information Theory,  Electrical Engineering and Systems Science - Signal Processing

@article{1903.03718,
     author = {Balatsoukas-Stimming, Alexios and Casta\~neda, Oscar and Jacobsson, Sven and Durisi, Giuseppe and Studer, Christoph},
     title = {Neural-Network Optimized 1-bit Precoding for Massive MU-MIMO},
     journal = {arXiv},
     volume = {2019},
     number = {0},
     year = {2019},
     language = {en},
     url = {http://dml.mathdoc.fr/item/1903.03718}
}

Balatsoukas-Stimming, Alexios; Castañeda, Oscar; Jacobsson, Sven; Durisi, Giuseppe; Studer, Christoph. Neural-Network Optimized 1-bit Precoding for Massive MU-MIMO. arXiv, Tome 2019 (2019) no. 0, . http://gdmltest.u-ga.fr/item/1903.03718/