Full-Duplex Amplify-and-Forward MIMO Relaying: Design and Performance Analysis Under Erroneous CSI and Hardware Impairments

Omid Taghizadeh,Giuseppe Thadeu Freitas De Abreu,Hiroki Iimori,Slawomir Stanczak

doi:10.1109/ojcoms.2021.3080239

Omid Taghizadeh, Giuseppe Thadeu Freitas De Abreu + Show 2 more

Open Access

https://doi.org/10.1109/ojcoms.2021.3080239

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Abstract

Full-duplex amplify-and-forward multiple-input multiple-output relaying has been the focus of several recent studies, due to the potential for achieving a higher spectral efficiency and lower latency, together with inherent processing simplicity. However, when the impact of hardware distortions are considered, such relays suffer from a distortion-amplification loop , due to the inter-dependent nature of the relay transmit signal covariance and the residual self-interference covariance. The aforementioned behavior leads to a significant performance degradation for a system with a low or medium hardware accuracy. In this work, we analyze the relay transfer function as well as the mean squared-error performance of a full-duplex amplify-and-forward multiple-input multiple-output relaying communication, under the impact of collective sources of additive and multiplicative transmit and receive impairments. Building on the performed analysis, an optimization problem is devised to minimize the communication Mean Squared-Error and solved by employing the recently proposed penalty dual-decomposition framework. The proposed solution converges to a stationary point of the original problem via a sequence of convex quadratic programs, thereby enjoying an acceptable arithmetic complexity as the problem dimensions grow large. Numerical simulations verify the significance of the proposed distortion-aware design and analysis, compared to the common simplified approaches, as the hardware accuracy degrades.

Highlights

F ULL-DUPLEX (FD) relays have been the focus of several recent studies, due to their potential to achieve a higher level of spectral efficiency and a lower end-to-end latency, compared to their Half-Duplex (HD) counterparts
This is because an FD relay has the capability to transmit and receive the relayed signal at the same time and frequency, enabled by the recently-developed SelfInterference Cancellation (SIC) techniques, e.g., [1]–[4], which provide an adequate level of isolation between transmit (Tx) and receive (Rx) directions motivating a wide range of related applications, see, e.g., [5], [6]
In this work we focus on the application of FD multiple-input multiple-output (MIMO) relays operating with an Amplify-and-Forward (AF) processing protocol

Summary

Introduction

F ULL-DUPLEX (FD) relays have been the focus of several recent studies, due to their potential to achieve a higher level of spectral efficiency and a lower end-to-end latency, compared to their Half-Duplex (HD) counterparts This is because an FD relay has the capability to transmit and receive the relayed signal at the same time and frequency, enabled by the recently-developed SelfInterference Cancellation (SIC) techniques, e.g., [1]–[4], which provide an adequate level of isolation between transmit (Tx) and receive (Rx) directions motivating a wide range of related applications, see, e.g., [5], [6]. TAGHIZADEH et al.: FD AMPLIFY-AND-FORWARD MIMO RELAYING: DESIGN AND PERFORMANCE ANALYSIS cancellation level may vary for different realistic conditions This mainly includes i) aging and inaccuracy of the hardware components, e.g., ADC and digital-to-analog-converter (DAC) noise, power amplifier and oscillator phase noise in analog domain, as well as ii) inaccurate estimation of the remaining interference paths due to the limited channel coherence time. It is essential to take into account the aforementioned inaccuracies to obtain a design which remains efficient under realistic situations

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