Linear Massive MIMO Uplink Detector Based On Joint Jacobi and Gauss-Seidel Methods

2020 16th International Conference on the Design of Reliable Communication Networks DRCN 2020 Pub Date : 2020-03-01 DOI:10.1109/DRCN48652.2020.1570610672

M. Albreem, Ayman A. El-Saleh, M. Juntti

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引用次数: 10

Abstract

In fifth generation (5G) cellular system, massive multiple-input multiple-output (MIMO) is utilized to improve the diversity gain, reliability, link robustness, latency, and power and spectral efficiencies. However, a large number of antennas requires sophisticated signal processing to detect data. Although the detection based on maximum likelihood (ML) obtains the best performance, it is not hardware friendly because of the exponential complexity. Therefore, several iterative methods are proposed to estimate the signal without computing the inverse of equalization matrix, and hence, minimize the complexity. The Jacobi (JA) and the Gauss-Seidel (GS) methods achieve a satisfactory performance. However, large iterations’ number is in demand which produces a high computational complexity. This paper proposes a detector for massive MIMO uplink (UL) system based on the JA and GS methods. Proposed detector obtains a balance between the performance and the complexity. In this research, initialization is performed based on the JA method. After-that, the estimation is performed based on the GS method. Numerical results show that the proposed JAGS detector outperforms the GS and the JA based detector. Moreover, proposed JA-GS based detector requires few iterations to obtain the target performance and hence, a considerable reduction in computational complexity is achieved.

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基于联合雅可比和高斯-塞德尔方法的线性海量MIMO上行探测器

在第五代(5G)蜂窝系统中，大规模多输入多输出(MIMO)被用于提高分集增益、可靠性、链路鲁棒性、延迟以及功率和频谱效率。然而，大量的天线需要复杂的信号处理来检测数据。尽管基于最大似然(ML)的检测获得了最好的性能，但由于其指数级的复杂性，它不是硬件友好的。因此，提出了几种不需要计算均衡矩阵逆的迭代方法来估计信号，从而使复杂度最小化。Jacobi (JA)和Gauss-Seidel (GS)方法取得了令人满意的性能。然而，需要大量的迭代次数，这就产生了很高的计算复杂度。本文提出了一种基于JA和GS方法的大规模MIMO上行系统检测器。所提出的检测器在性能和复杂度之间取得了平衡。在本研究中，基于JA方法进行初始化。然后，基于GS方法进行估计。数值结果表明，所提出的JAGS探测器优于基于GS和基于JA的探测器。此外，所提出的基于JA-GS的检测器只需很少的迭代即可获得目标性能，从而大大降低了计算复杂度。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2020 16th International Conference on the Design of Reliable Communication Networks DRCN 2020

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