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    Physics-informed data augmentation (PIDA) enhances radar-based human behavior recognition, especially for falls in aging populations. This method improves domain generalization by simulating realistic radar conditions and motion variations.

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    Area of Science:

    • Radar Signal Processing
    • Machine Learning for Human Behavior Analysis
    • Data Augmentation Techniques

    Background:

    • Falling is a critical safety concern, particularly for the aging population.
    • Radar-based human behavior recognition, especially for falls, is extensively studied.
    • Current methods suffer from poor generalization due to limited labeled data.

    Purpose of the Study:

    • To propose a novel physics-informed data augmentation (PIDA) strategy.
    • To enhance domain generalization (DG) for human behavior recognition using micro-Doppler signatures (m-DS) from FMCW radar.
    • To improve the accuracy and robustness of fall detection systems.

    Main Methods:

    • Developed PIDA, including Distance Data Augmentation (DDA) and Behavior Pattern Data Augmentation (BPDA).
    • DDA simulates electromagnetic attenuation across ranges; BPDA diversifies motion styles while preserving kinematics.
    • Integrated PIDA with a multi-source domain adversarial neural network (MSDAN) for transfer learning and invariant feature extraction.

    Main Results:

    • PIDA significantly improved average DG accuracy compared to baseline, traditional optical data augmentation (TODA), and generative data augmentation (GDA).
    • On own datasets, PIDA improved accuracy by 1.52%, 2.48%, and 4.88% over baseline, TODA, and GDA, respectively.
    • On public datasets, PIDA achieved improvements of 3.67%, 6.29%, and 9.78% over baseline, TODA, and GDA, respectively, with a small DG gap.

    Conclusions:

    • PIDA effectively addresses the data scarcity issue in radar-based human behavior recognition.
    • The proposed method demonstrates superior domain generalization capabilities for fall detection.
    • PIDA offers a promising approach for robust and accurate fall-related human behavior recognition systems.