A Simulation-Based Framework for the Design of Human Activity Recognition Systems Using Radar Sensors
Peer reviewed, Journal article
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Date
2023Metadata
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Original version
Waqar, S. & Pätzold, M. U. (2023). A Simulation-Based Framework for the Design of Human Activity Recognition Systems Using Radar Sensors. IEEE Internet of Things Journal, 11 (8), 14494-14507. https://doi.org/10.1109/JIOT.2023.3344179Abstract
Modern human activity recognition (HAR) systems are designed using large amounts of experimental data. So far, real-data-driven or experimental-based HAR systems using Wi-Fi or radar systems have shown considerable results. However, the acquisition of large, clean, and labeled training data sets remains a crucial impediment to the progress of experimental-based HAR systems. Therefore, in this article, a paradigm shift from the experimental to a fully simulation-based design of HAR systems is proposed in the context of radar sensing. An end-to-end simulation framework is proposed as a proof-of-concept that can simulate realistic millimeter-wave radar signatures for synthesized human motion. We designed a human motion synthesis tool that emulates different types of human activities and generates the spatial trajectories accordingly. These trajectories are processed by a geometric model with respect to user-defined antenna configurations. Considering the long- and short-time stationarity of wireless channels, we synthesize the raw in-phase and quadrature data and process the data to simulate the radar signatures for emulated human activities. Finally, a simulated and a real HAR data set were used to train and test a simulation-based HAR system, respectively, which gave an average (maximum) classification accuracy of 94% (98.4%). The main advantage of the proposed simulation framework is that the training effort for radar-based classifiers, e.g., gesture recognition systems, can be minimized drastically.