针对多径近场信道的启用 RIS 的时间逆转方案

IF 3.7 3区计算机科学 Q2 TELECOMMUNICATIONS

IEEE Communications Letters Pub Date : 2024-08-12 DOI:10.1109/LCOMM.2024.3441756

Andreas Nicolaides;Constantinos Psomas;Ioannis Krikidis

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引用次数: 0

摘要

时间反转（TR）是一种利用多径实现高频宽带通信能量聚焦的前景广阔的技术。在这封信中，我们重点讨论了一种由可重构智能表面（RIS）促进的时间反转方案，由于频率较高和阵列孔径较大，该方案可在近场区域工作。在这种弱散射条件下，所提出的方案丰富了 TR 的传播环境，而且 RIS 配置不需要信道知识。具体来说，利用 RIS 创建多个虚拟传播路径是有效应用 TR 所必需的。我们通过接收信噪比（SNR）推导出了近场建模下拟议方案的性能边界，并研究了各种系统设计参数对性能的影响。我们发现，线性 RIS 拓扑能最大限度地增加可解析路径的数量。此外，我们还证明了所提出的方案能提高信噪比，而对于大量元素而言，其性能优于 RIS 上的传统无源波束成形。

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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An RIS-Enabled Time Reversal Scheme for Multipath Near-Field Channels

Time reversal (TR) is a promising technique that exploits multipaths for achieving energy focusing in high-frequency wideband communications. In this letter, we focus on a TR scheme facilitated by a reconfigurable intelligent surface (RIS) which, due to the higher frequency and large array aperture, operates in the near-field region. The proposed scheme enriches the propagation environment for the TR in such weak scattering conditions and does not need channel knowledge for the RIS configuration. Specifically, the RIS is employed to create multiple virtual propagation paths that are required to efficiently apply the TR. We derive a performance bound for the proposed scheme under near-field modeling through the received signal-to-noise ratio (SNR) and we examine how various system design parameters affect the performance. We observe that a linear RIS topology maximizes the number of resolvable paths. It is also demonstrated that the proposed scheme improves the SNR, while for a large number of elements it can outperform the conventional passive beamforming at the RIS.

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来源期刊

IEEE Communications Letters 工程技术-电信学

CiteScore

8.10

自引率

7.30%

发文量

590

审稿时长

2.8 months

期刊介绍： The IEEE Communications Letters publishes short papers in a rapid publication cycle on advances in the state-of-the-art of communication over different media and channels including wire, underground, waveguide, optical fiber, and storage channels. Both theoretical contributions (including new techniques, concepts, and analyses) and practical contributions (including system experiments and prototypes, and new applications) are encouraged. This journal focuses on the physical layer and the link layer of communication systems.