Signal Classification with Linear Phase Modulation for RIS-Assisted Near-Field Localization

GLOBECOM 2022 - 2022 IEEE Global Communications Conference Pub Date : 2022-12-04 DOI:10.1109/GLOBECOM48099.2022.10000864

Jeongwan Kang, Seung-Woo Ko, Sunwoo Kim

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Abstract

Reconfigurable intelligent surface (RIS), one core element in 6G, opens a new opportunity to design near-field (NF) localization since a signal's propagation distance can be different depending on the reflected points on large RIS. For the design of NF localization to be effective, signals reflected on distinct RIS points should be profiled without interfering with the others, called signal classification (SC). In this paper, we propose a simple yet novel SC technique, called linear phase modulation (LPM), where sequences of distant RIS elements' phases are linearly modulated with different rates. Along with the conventional or-thogonal frequency division multiplexing waveform, LPM makes it possible to classify the reflected signals by distant RIS elements as well as estimate their propagation distances using a two-dimensional Fourier transform (2D-FT) technique. It exploits one more signal dimension for performance improvement than conventional one-dimensional FT (1D-FT) based SC. Through analytic and numerical studies, we verify the effectiveness of the proposed SC using LPM by comparing its localization accuracy with several benchmarks designed based on 1D-FT.

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基于线性相位调制的近场定位信号分类

可重构智能表面(RIS)是6G的核心元素之一，它为设计近场定位(NF)提供了新的机会，因为信号的传播距离可能取决于大型RIS上的反射点。为了有效地设计NF定位，必须在不干扰其他RIS点的情况下对反射在不同RIS点上的信号进行剖面分析，称为信号分类(SC)。在本文中，我们提出了一种简单而新颖的SC技术，称为线性相位调制(LPM)，其中远距离RIS元素的相位序列以不同的速率线性调制。与传统的或正交频分复用波形一起，LPM可以通过远距离RIS元素对反射信号进行分类，并使用二维傅里叶变换(2D-FT)技术估计其传播距离。与传统的一维傅里叶变换(1D-FT)相比，它利用了多一个信号维度来提高性能。通过分析和数值研究，我们通过将LPM的定位精度与基于一维傅里叶变换设计的几个基准进行比较，验证了基于LPM的SC的有效性。

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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GLOBECOM 2022 - 2022 IEEE Global Communications Conference

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