基于毫米波雷达的室内环境感知多人跟踪

IF 3.6 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies Pub Date : 2023-09-27 DOI:10.1145/3610902
Weiyan Chen, Hongliu Yang, Xiaoyang Bi, Rong Zheng, Fusang Zhang, Peng Bao, Zhaoxin Chang, Xujun Ma, Daqing Zhang
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引用次数: 1

摘要

商用毫米波雷达的无设备室内定位和跟踪由于其非侵入性和高空间分辨率而引起了人们的广泛关注。然而,由于室内环境中存在丰富的多径反射和遮挡,难以达到较高的跟踪精度。具有不可忽略的毫米波信号反射率的静态物体与移动的人体主体相互作用,产生时变多径鬼影和阴影鬼影,容易与真实主体混淆。为了描述复杂的相互作用,我们首先开发了一个几何模型,根据人类和静态反射器的位置估计多路径鬼的位置。基于该模型,当一个人沿着任意轨迹穿越环境时,根据接收到的雷达信号自动估计形成反射图的静态反射器的位置。反射图允许消除多径和阴影幽灵干扰,以及增强在遮挡区域弱反射的人类受试者。本文提出的环境感知多人跟踪系统,在4个具有代表性的室内空间中,使用单根毫米波雷达,可生成平均误差为15.5cm、90百分位误差为30.3cm的反射图,平均误差为8.6cm、90百分位误差为17.5cm的多人跟踪精度。
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Environment-aware Multi-person Tracking in Indoor Environments with MmWave Radars
Device-free indoor localization and tracking using commercial millimeter wave radars have attracted much interest lately due to their non-intrusive nature and high spatial resolution. However, it is challenging to achieve high tracking accuracy due to rich multipath reflection and occlusion in indoor environments. Static objects with non-negligible reflectance of mmWave signals interact with moving human subjects and generate time-varying multipath ghosts and shadow ghosts, which can be easily confused as real subjects. To characterize the complex interactions, we first develop a geometric model that estimates the location of multipath ghosts given the locations of humans and static reflectors. Based on this model, the locations of static reflectors that form a reflection map are automatically estimated from received radar signals as a single person traverses the environment along arbitrary trajectories. The reflection map allows for the elimination of multipath and shadow ghost interference as well as the augmentation of weakly reflected human subjects in occluded areas. The proposed environment-aware multi-person tracking system can generate reflection maps with a mean error of 15.5cm and a 90-percentile error of 30.3cm, and achieve multi-person tracking accuracy with a mean error of 8.6cm and a 90-percentile error of 17.5cm, in four representative indoor spaces with diverse subjects using a single mmWave radar.
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来源期刊
Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies
Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies Computer Science-Computer Networks and Communications
CiteScore
9.10
自引率
0.00%
发文量
154
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