Towards a Dynamic Fresnel Zone Model to WiFi-based Human Activity Recognition
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Published:2023-06-12
Issue:2
Volume:7
Page:1-24
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ISSN:2474-9567
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Container-title:Proceedings of the ACM on Interactive, Mobile, Wearable and Ubiquitous Technologies
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language:en
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Short-container-title:Proc. ACM Interact. Mob. Wearable Ubiquitous Technol.
Author:
Liu Jinyi1ORCID, Li Wenwei2ORCID, Gu Tao3ORCID, Gao Ruiyang4ORCID, Chen Bin5ORCID, Zhang Fusang6ORCID, Wu Dan2ORCID, Zhang Daqing7ORCID
Affiliation:
1. Peking University, Key Laboratory of High Confidence Software Technologies (Ministry of Education), School of Electronics Engineering and Computer Science, Beijing, China 2. Peking University, Beijing, China 3. Macquarie Univerisity, Department of Computing, Macquarie University, Sydney, Australia 4. ZEKU Technology, Co., Ltd, Beijing, China 5. Lijiang culture and tourism college, Key Laboratory of High Confidence Software Technologies (Ministry of Education), School of Electronics Engineering and Computer Science, Beijing, China 6. Institute of Software, Chinese Academy of Sciences and University of Chinese Academy of Sciences, Beijing, China 7. Key Laboratory of High Confidence Software Technologies (Ministry of Education), School of Electronics Engineering and Computer Science, Peking University, Beijing, China, IP Paris and Telecom SudParis, Evry, France
Abstract
The passive WiFi sensing research has largely centered on activity sensing using fixed-location WiFi transceivers, leading to the development of several theoretical models that aim to map received WiFi signals to human activity. Of these models, the Fresnel zone model has shown to be particularly noteworthy. However, the growing popularity of mobile WiFi receivers has not been matched by corresponding research on mobile receiver-based theoretical models. This paper fills this gap by presenting the first theoretical model to quantify the impact of moving a moving receiver for WiFi sensing. We propose a novel dynamic Fresnel zone model in the free space of an indoor environment, which takes the form of a cluster of concentric hyperbolas centered on the transmitter and reflection subject. We examine three properties of this model, i.e., relating the variation in RF signals received by the receiver to the position and orientation of the human, the movement of the receiver, and the presence of other objects in the environment. To validate this model, we develop a prototype system and conduct extensive experiments. The results are consistent with our theoretical analysis, and the system is able to detect the direction of the transmitter with an accuracy of 10° or better, measure the receiver's relative motion displacement within 1 cm a millimeter-level accuracy, and classify five receiver-side activities with an accuracy of 98%. Our work moves a significant step forward in WiFi sensing and may potentially open up new avenues for future research.
Funder
the National Natural Science Foundation of China the National Natural Science Foundation of China A3 Foresight Program the Youth Innovation Promotion Association, Chinese Academy of Sciences the Beijing Nova Program the Beijing Natural Science Foundation the PKU-NTU Collaboration Project
Publisher
Association for Computing Machinery (ACM)
Subject
Computer Networks and Communications,Hardware and Architecture,Human-Computer Interaction
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