Frequency-modulated continuous-wave radar enables the non-contact and privacy-preserving recognition of human behavior. However, the accuracy of behavior recognition is directly influenced by the spatial relationship between human posture and the radar. To address the issue of low accuracy in behavior recognition when the human body is not directly facing the radar, a method combining local outlier factor with Doppler information is proposed for the correction of multi-classifier recognition results. Initially, the information such as distance, velocity, and micro-Doppler spectrogram of the target is obtained using the fast Fourier transform and histogram of oriented gradients - support vector machine methods, followed by preliminary recognition. Subsequently, Platt scaling is employed to transform recognition results into confidence scores, and finally, the Doppler - local outlier factor method is utilized to calibrate the confidence scores, with the highest confidence classifier result considered as the recognition outcome. Experimental results demonstrate that this approach achieves an average recognition accuracy of 96.23% for comprehensive human behavior recognition in various orientations.
Sun Chang, Wang Shaohong, Lin Yanping
. Omnidirectional Human Behavior Recognition Method Based on Frequency-Modulated Continuous-Wave Radar[J]. Journal of Shanghai Jiaotong University(Science), 2025
, 30(4)
: 637
-645
.
DOI: 10.1007/s12204-024-2580-z
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