Joint Localization and Communication Enhancement in Uplink Integrated Sensing and Communications System With Clock Asynchronism

Xu Chen;Xinxin He;Zhiyong Feng;Zhiqing Wei;Qixun Zhang;Xin Yuan;Ping Zhang
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Abstract

In this paper, we propose a joint single-base localization and communication enhancement scheme for the uplink (UL) integrated sensing and communications (ISAC) system with asynchronism, which can achieve accurate single-base localization of user equipment (UE) and significantly improve the communication reliability despite the existence of timing offset (TO) due to the clock asynchronism between UE and base station (BS). Our proposed scheme integrates the CSI enhancement into the multiple signal classification (MUSIC)-based AoA estimation and thus imposes no extra complexity on the ISAC system. We further exploit a MUSIC-based range estimation method and prove that it can suppress the time-varying TO-related phase terms. Exploiting the AoA and range estimation of UE, we can estimate the location of UE. Finally, we propose a joint CSI and data signals-based localization scheme that can coherently exploit the data and the CSI signals to improve the AoA and range estimation, which further enhances the single-base localization of UE. The extensive simulation results show that the enhanced CSI can achieve equivalent bit error rate performance to the minimum mean square error (MMSE) CSI estimator. The proposed joint CSI and data signals-based localization scheme can achieve decimeter-level localization accuracy despite the existing clock asynchronism and improve the localization root mean square error (RMSE) by about 6 dB compared with the maximum likelihood esimation (MLE)-based benchmark method.
具有时钟异步性的上行链路综合传感与通信系统中的联合定位与通信增强功能
本文为具有异步性的上行链路(UL)综合传感与通信(ISAC)系统提出了一种联合单基站定位和通信增强方案,尽管用户设备(UE)和基站(BS)之间存在时钟异步导致的定时偏移(TO),该方案仍能实现用户设备(UE)的精确单基站定位,并显著提高通信可靠性。我们提出的方案将 CSI 增强集成到基于多信号分类(MUSIC)的 AoA 估计中,因此不会给 ISAC 系统带来额外的复杂性。我们还进一步利用了基于 MUSIC 的测距估计方法,并证明它可以抑制与 TO 相关的时变相位项。利用 UE 的 AoA 和测距估计,我们可以估计出 UE 的位置。最后,我们提出了一种基于 CSI 和数据信号的联合定位方案,该方案可以连贯地利用数据和 CSI 信号来改进 AoA 和距离估计,从而进一步增强了 UE 的单基地定位能力。大量仿真结果表明,增强型 CSI 可实现与最小均方误差 (MMSE) CSI 估计器相当的误码率性能。与基于最大似然估计(MLE)的基准方法相比,所提出的基于 CSI 和数据信号的联合定位方案可在现有时钟不同步的情况下实现分米级定位精度,并将定位均方根误差(RMSE)提高约 6 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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