异步感知车载网络中的杂波抑制、时频同步和感知参数关联

Xiao-Yang Wang;Shaoshi Yang;Jianhua Zhang;Christos Masouros;Ping Zhang
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引用次数: 0

摘要

在依赖新兴的综合传感与通信(ISAC)技术的实用感知车辆网络(PVN)中实现精确定位和速度估计仍面临重大挑战。首先,复杂的无线传播环境会产生不必要的杂波,从而降低车辆感知性能并增加计算复杂度。其次,在实际的 PVN 中,单独估算的多类参数与特定车辆的关联性不强,这可能会导致多车定位中的误差传播。第三,PVN 中的无线电收发器天然是异步的,这会导致车辆感知中强烈的范围和速度模糊性。为了克服这些挑战,本文 1) 引入了一种基于移动目标指示(MTI)的杂波抑制和感知联合算法,并分析了其杂波抑制性能以及使用所提出的杂波抑制算法进行成对测距-速度估计时的 Cramér-Rao 下限(CRLB);2)我们设计了一种算法(及其低复杂度版本),用于将单个到达方向(DOA)估计值与基于 "域变换 "的成对测距-速度估计值联系起来;3)我们提出了第一种可行的载波频率偏移(CFO)和时间偏移(TO)估计算法,支持非视距(NLOS)环境下的无源车辆传感。该算法将静态物体反射信号的延迟-多普勒频谱视为特定环境的 "指纹频谱",并证明在改变载波频率偏移和/或时间偏移时,该频谱会表现出圆周偏移特性。然后,通过获取圆周偏移的次数来有效估计 CFO 和 TO,我们还分析了拟议时频同步算法的均方误差 (MSE) 性能。最后,仿真结果表明了我们的算法在不同配置下的性能优势,同时也证实了理论分析。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Clutter Suppression, Time-Frequency Synchronization, and Sensing Parameter Association in Asynchronous Perceptive Vehicular Networks
Significant challenges remain for realizing precise positioning and velocity estimation in practical perceptive vehicular networks (PVN) that rely on the emerging integrated sensing and communication (ISAC) technology. Firstly, complicated wireless propagation environment generates undesired clutter, which degrades the vehicular sensing performance and increases the computational complexity. Secondly, in practical PVN, multiple types of parameters individually estimated are not well associated with specific vehicles, which may cause error propagation in multiple-vehicle positioning. Thirdly, radio transceivers in a PVN are naturally asynchronous, which causes strong range and velocity ambiguity in vehicular sensing. To overcome these challenges, in this paper 1) we introduce a moving target indication (MTI) based joint clutter suppression and sensing algorithm, and analyze its clutter-suppression performance and the Cramér-Rao lower bound (CRLB) of the paired range-velocity estimation upon using the proposed clutter suppression algorithm; 2) we design an algorithm (and its low-complexity versions) for associating individual direction-of-arrival (DOA) estimates with the paired range-velocity estimates based on “domain transformation”; 3) we propose the first viable carrier frequency offset (CFO) and time offset (TO) estimation algorithm that supports passive vehicular sensing in non-line-of-sight (NLOS) environments. This algorithm treats the delay-Doppler spectrum of the signals reflected by static objects as an environment-specific “fingerprint spectrum”, which is shown to exhibit a circular shift property upon changing the CFO and/or TO. Then, the CFO and TO are efficiently estimated by acquiring the number of circular shifts, and we also analyse the mean squared error (MSE) performance of the proposed time-frequency synchronization algorithm. Finally, simulation results demonstrate the performance advantages of our algorithms under diverse configurations, while corroborating the theoretical analysis.
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