Intelligent Reflecting Surfaces Assisted Millimeter Wave MIMO Full Duplex Systems

TL;DR

This paper introduces a novel near-field IRS-assisted millimeter wave full-duplex system that reduces hardware costs and power consumption while achieving superior self-interference cancellation and system performance.

Contribution

It proposes replacing hybrid beamforming with near-field IRSs for efficient self-interference mitigation and presents a joint active-passive beamforming design for improved sum-rate performance.

Findings

Near-field IRSs significantly outperform conventional systems in SI cancellation.

The proposed joint beamforming achieves higher sum-rate gains.

System reduces hardware complexity and power consumption.

Abstract

Full duplex (FD) systems suffer from very high hardware cost and high power consumption to mitigate the self-interference (SI) in the analog domain. Moreover, in millimeter wave (mmWave) they rely on hybrid beamforming (HYBF) as a signal processing tool to partially deal with the SI, which presents many drawbacks such as high insertion loss and high power consumption. This article proposes the use of near-field (NF-) IRSs for FD systems with the objective to solve the aforementioned issues cost-efficiently. Namely, we propose to truncate the analog/hybrid beamforming stage of the mmWave FD systems and compensate it with an NF-IRS, to simultaneously and smartly control the uplink (UL) and downlink (DL) channels, while assisting in shaping the SI channel: this to obtain very strong passive SI cancellation. A novel joint active and passive beamforming design for the weighted sum-rate (WSR) maximization of a NF-IRS-assisted mmWave point-to-point FD system is presented. Results show that the proposed solution fully reaps the benefits of the IRSs only when they operate in the NF, which leads to considerably higher gains compared to the conventional massive MIMO (mMIMO) mmWave FD and half duplex (HD) systems.