A Scalable Precoding Processor for Large-Scale MU-MIMO Systems

The number of devices served by baseband stations is constantly increasing due to the rising data traffic in modern communication systems. In order to support large-scale multi-user multiple-input multiple-output (MU-MIMO) systems and achieve their capacity, it is necessary to consider power allocation and user selection along with precoding. This paper introduces a scalable MU-MIMO precoding processor that solves the joint optimization problem for precoding, power allocation, and user selection. We define custom vector instructions and dedicate vector arithmetic operators based on the RV32IM instruction set architecture to efficiently support various MU-MIMO baseband processing scenarios. The proposed vector operators include parallel dual-precision multipliers to enable energy-efficient processing by adjusting the computing resolution of each step without degrading the algorithm-level quality. The proposed processor is fabricated using 28nm CMOS technology and is capable of solving the state-of-the-art joint optimization problem in only 0.51ms for the $64\times 64$ large-scale MU-MIMO configuration. Our processor achieves up to 17.4 times higher processing efficiency compared to previous precoder design, even when supporting the largest number of users and the most complicated algorithm.