Beamforming for Sensing: Hybrid Beamforming based on Transmitter-Receiver Collaboration for Millimeter-Wave Sensing

IF 3.6 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies Pub Date : 2024-05-13 DOI:10.1145/3659619

Long Fan, Lei Xie, Wenhui Zhou, Chuyu Wang, Yanling Bu, Sanglu Lu

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Abstract

Previous mmWave sensing solutions assumed good signal quality. Ensuring an unblocked or strengthened LoS path is challenging. Therefore, finding an NLoS path is crucial to enhancing perceived signal quality. This paper proposes Trebsen, a Transmitter-REceiver collaboration-based Beamforming scheme SENsing using commercial mmWave radars. Specifically, we define the hybrid beamforming problem as an optimization challenge involving beamforming angle search based on transmitter-receiver collaboration. We derive a comprehensive expression for parameter optimization by modeling the signal attenuation variations resulting from the propagation path. To comprehensively assess the perception signal quality, we design a novel metric perceived signal-to-interference-plus-noise ratio (PSINR), combining the carrier signal and baseband signal to quantify the fine-grained sensing motion signal quality. Considering the high time cost of traversing or randomly searching methods, we employ a search method based on deep reinforcement learning to quickly explore optimal beamforming angles at both transmitter and receiver. We implement Trebsen and evaluate its performance in a fine-grained sensing application (i.e., heartbeat). Experimental results show that Trebsen significantly enhances heartbeat sensing performance in blocked or misaligned LoS scenes. Comparing non-beamforming, Trebsen demonstrates a reduction of 23.6% in HR error and 27.47% in IBI error. Moreover, comparing random search, Trebsen exhibits a 90% increase in search speed.

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传感波束成形：基于发射机-接收机协作的混合波束成形用于毫米波传感

以前的毫米波传感解决方案假定信号质量良好。确保无阻塞或增强的 LoS 路径具有挑战性。因此，找到一条 NLoS 路径对于提高感知信号质量至关重要。本文提出的 Trebsen 是一种基于发射机-接收机协作的波束成形方案，利用商用毫米波雷达进行 SENsing。具体来说，我们将混合波束成形问题定义为一个优化挑战，涉及基于发射机-接收机协作的波束成形角度搜索。通过对传播路径造成的信号衰减变化进行建模，我们得出了参数优化的综合表达式。为了全面评估感知信号质量，我们设计了一种新的感知信号干扰加噪声比（PSINR）指标，结合载波信号和基带信号来量化细粒度感知运动信号质量。考虑到遍历或随机搜索方法的时间成本较高，我们采用了一种基于深度强化学习的搜索方法，以快速探索发射器和接收器的最佳波束成形角度。我们实现了 Trebsen，并评估了它在细粒度传感应用（即心跳）中的性能。实验结果表明，Trebsen 显著提高了在阻塞或错位 LoS 场景中的心跳传感性能。与非波束成形相比，Trebsen 将 HR 误差降低了 23.6%，将 IBI 误差降低了 27.47%。此外，与随机搜索相比，Trebsen 的搜索速度提高了 90%。

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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