Rate-Splitting Robustness in Multi-Pair Massive MIMO Relay Systems

TL;DR

This paper investigates the robustness of rate-splitting in multi-pair massive MIMO relay systems, demonstrating its advantages in full-duplex operation and analyzing the impact of self-interference and system parameters.

Contribution

It introduces a deterministic equivalent analysis for rate-splitting in massive MIMO relay systems, highlighting its robustness and performance benefits under imperfect channel knowledge.

Findings

Rate-splitting enhances sum-rate in half-duplex systems without saturation.

FD relays outperform HD when combined with rate-splitting, even with self-interference.

Increasing relay antennas improves rate-splitting efficacy, especially under imperfect CSIT.

Abstract

Relay systems improve both coverage and system capacity. Towards this direction, full-duplex (FD) technology, being able to boost the spectral efficiency by transmitting and receiving simultaneously on the same frequency and time resources, is envisaged to play a key role in future networks. However, its benefits come at the expense of self-interference (SI) from their own transmit signal. At the same time, massive MIMO systems, bringing unconventionally many antennas, emerge as a promising technology with huge degrees-of-freedom (DoF). To this end, this paper considers a multi-pair decode-and-forward FD relay channel, where the relay station is deployed with a large number of antennas. Moreover, the rate-splitting (RS) transmission has recently been shown to provide significant performance benefits in various multi-user scenarios with imperfect channel state information at the transmitter (CSIT). Engaging the RS approach, we employ the deterministic equivalent (DE) analysis to derive the corresponding sum-rates in the presence of interferences. Initially, numerical results demonstrate the robustness of RS in half-duplex (HD) systems, since the achievable sum-rate increases without bound, i.e., it does not saturate at high signal-to-noise ratio (SNR). Next, we tackle the detrimental effect of SI in FD. In particular, and most importantly, not only FD outperforms HD, but also RS enables increasing the range of SI over which FD outperforms HD. Furthermore, increasing the number of relay station antennas, RS appears to be more efficacious due to imperfect CSIT, since SI decreases. Interestingly, increasing the number of users, the efficiency of RS worsens and its implementation becomes less favorable under these conditions. Finally, we verify that the proposed DEs, being accurate for a large number of relay station antennas, are tight approximations even for realistic system dimensions.