MMSE-based lattice-reduction-aided fixed-complexity sphere decoder for low-complexity near-ML MIMO detection

The 21st IEEE International Workshop on Local and Metropolitan Area Networks Pub Date : 2015-04-22 DOI:10.1109/LANMAN.2015.7114716

Hyunsub Kim, Hyukyeon Lee, Jaeseok Kim

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引用次数: 6

Abstract

In this paper, we propose a minimum-mean-squared-error (MMSE)-based lattice-reduction (LR)-aided fixed-complexity sphere decoder (FSD) for low-complexity near-maximum-likelihood (near-ML) multiple-input multiple-output (MIMO) detection. In order for the FSD to achieve optimal performance, the number of full expansion (FE) stages should be sufficient, which is the major cause of the increase in the computational complexity when either a large signal constellation or a large number of antennas are adopted. However, the proposed algorithm maintains the near-ML performance with the aid of the MMSE-based LR algorithm while reducing the number of FE stages. Although there exists the increase in the computational complexity for the application of the additional processing elements, the decrease in the number of FE stages results in the lower computational complexity of the overall algorithm. The numerical analysis demonstrates that there is a considerable decrease in the computational complexity while the performance degradation is negligible, compared to the optimal FSD.

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基于mmse的栅格约简辅助固定复杂度球面解码器，用于低复杂度近ml MIMO检测

在本文中，我们提出了一种基于最小均方误差(MMSE)的栅格缩减(LR)辅助固定复杂度球体解码器(FSD)，用于低复杂度近最大似然(近ml)多输入多输出(MIMO)检测。为了使FSD达到最优的性能，充分展开(FE)级的数量必须足够，这是在采用大信号星座或大量天线时计算复杂度增加的主要原因。然而，该算法在基于mmse的LR算法的帮助下保持了接近ml的性能，同时减少了FE阶段的数量。虽然应用额外的处理元素会增加计算复杂度，但FE阶段数量的减少会导致整体算法的计算复杂度降低。数值分析表明，与最优FSD相比，计算复杂度显著降低，而性能下降可以忽略不计。

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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The 21st IEEE International Workshop on Local and Metropolitan Area Networks

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