Weller, PascalPascalWellerAziz, FadyFadyAzizAbdulatif, SherifSherifAbdulatifSchneider, UrsUrsSchneiderHuber, Marco F.Marco F.Huber2023-06-152023-06-152022https://publica.fraunhofer.de/handle/publica/4429382-s2.0-85141010422Radar for deep learning-based human identification has become a research area of increasing interest. It has been shown that micro-Doppler (µ-D) can reflect the walking behavior, through capturing the periodic limbs micro-motions. One of the main aspects is maximizing the number of included classes, while considering the real-time and training dataset size constraints. In this paper, a multiple-input-multiple-output (MIMO) radar is used to formulate micro-motion spectrograms of the elevation angular velocity (µ-ω). The effectiveness of concatenating this newly-formulated spectrogram with the commonly used µ-D ones is investigated. To accommodate for non-constrained real walking motion, an adaptive cycle segmentation framework is utilized and a metric learning network is trained on half gait cycles (≈0.5 s). Studies on the effects of various numbers of classes (5-20), different dataset sizes, and varying observation time windows (1-2 s) are conducted. A non-constrained walking dataset of 22 subjects is collected with different aspect angles with respect to the radar. The proposed few-shot learning (FSL) approach achieves a classification error of 11.3 % with only 2 min of training data per subject.enfew-shot learninghuman identificationmicro-motionRadartriplet lossconference paper