Blind Beamforming for Coverage Enhancement With Intelligent Reflecting Surface

IF 8.9 1区计算机科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Wireless Communications Pub Date : 2024-07-26 DOI:10.1109/TWC.2024.3431291

Fan Xu;Jiawei Yao;Wenhai Lai;Kaiming Shen;Xin Li;Xin Chen;Zhi-Quan Luo

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引用次数: 0

Abstract

Conventional policy for configuring an intelligent reflecting surface (IRS) typically requires channel state information (CSI), thus incurring substantial overhead costs and facing incompatibility with the current network protocols. This paper proposes a blind beamforming strategy in the absence of CSI, aiming to boost the minimum signal-to-noise ratio (SNR) among all the receiver positions, namely the coverage enhancement. Although some existing works already consider the IRS-assisted coverage enhancement without CSI, they assume certain position-channel models through which the channels can be recovered from the geographic locations. In contrast, our approach solely relies on the received signal power data, not assuming any position-channel model. We examine the achievability and converse of the proposed blind beamforming method. If the IRS has N reflective elements and there are U receiver positions, then our method guarantees the minimum SNR of

$\Omega (N^{2}/U)$

—which is fairly close to the upper bound

$O(N+N^{2}\sqrt {\ln (NU)}/\sqrt [{4}]{U})$

. Aside from the simulation results, we justify the practical use of blind beamforming in a field test at 2.6 GHz. According to the real-world experiment, the proposed blind beamforming method boosts the minimum SNR across seven random positions in a conference room by 18.22 dB, while the position-based method yields a boost of 12.08 dB.

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利用智能反射面进行盲波束成形以增强覆盖范围

传统的智能反射面（IRS）配置策略通常需要信道状态信息（CSI），因此会产生大量的开销成本，并面临与当前网络协议不兼容的问题。本文提出了一种无 CSI 的盲波束成形策略，旨在提高所有接收器位置之间的最小信噪比（SNR），即覆盖增强。虽然现有的一些研究已经考虑了无 CSI 的 IRS 辅助覆盖增强，但它们假设了某些位置-信道模型，通过这些模型可以从地理位置恢复信道。相比之下，我们的方法只依赖接收到的信号功率数据，不假设任何位置信道模型。我们研究了盲波束成形方法的可实现性和反向性。如果 IRS 有 N 个反射元素，并且有 U 个接收器位置，那么我们的方法可以保证最小信噪比为 $\Omega (N^{2}/U)$ --这与上限 $O(N+N^{2}\sqrt {\ln (NU)}/\sqrt [{4}]{U})$ 非常接近。除了仿真结果，我们还在 2.6 GHz 的现场测试中证明了盲波束成形的实际应用。根据实际实验结果，所提出的盲波束成形方法可将会议室中七个随机位置的最小信噪比提高 18.22 dB，而基于位置的方法只能提高 12.08 dB。

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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来源期刊

IEEE Transactions on Wireless Communications 工程技术-电信学

CiteScore

18.60

自引率

10.60%

发文量

708

审稿时长

5.6 months

期刊介绍： The IEEE Transactions on Wireless Communications is a prestigious publication that showcases cutting-edge advancements in wireless communications. It welcomes both theoretical and practical contributions in various areas. The scope of the Transactions encompasses a wide range of topics, including modulation and coding, detection and estimation, propagation and channel characterization, and diversity techniques. The journal also emphasizes the physical and link layer communication aspects of network architectures and protocols. The journal is open to papers on specific topics or non-traditional topics related to specific application areas. This includes simulation tools and methodologies, orthogonal frequency division multiplexing, MIMO systems, and wireless over optical technologies. Overall, the IEEE Transactions on Wireless Communications serves as a platform for high-quality manuscripts that push the boundaries of wireless communications and contribute to advancements in the field.