Abstract
The capability of sensors to identify individuals in a specific scenario is a topic of high relevance for sensitive sectors such as public security. A traditional approach involves cameras; however, camera-based surveillance systems lack discretion and have high computational and storing requirements in order to perform human identification. Moreover, they are strongly influenced by external factors (e.g., light and weather). This paper proposes an approach based on a temporal convolutional deep neural networks classifier applied to radar micro-Doppler signatures in order to identify individuals. Both sensor and processing requirements ensure a low size weight and power profile, enabling large scale deployment of discrete human identification systems. The proposed approach is assessed on real data concerning 106 individuals. The results show good accuracy of the classifier (the best obtained accuracy is 0.89 with an F1-score of 0.885) and improved performance when compared to other standard approaches.
Highlights
A challenging and critical task in the video-surveillance domain is quick and accurate individual identification
With respect to the above literature, this study proposes the adoption of a temporal convolutional networks (TCNs) classifier to identify individuals from the micro-Doppler data
Looking at the 100-targets TCN classifier, we notice that the best accuracy (0.89)
Summary
A challenging and critical task in the video-surveillance domain is quick and accurate individual identification. Since data produced by a FMCW data is suitable for neural-networks processing, it is worthwhile investigating the adoption of Deep Learning (DL) algorithms for the gait-based human recognition using micro-Doppler signatures as features [13,14,15,16]. DL, taking inspiration by the way information is processed in biological nervous systems and their neurons, represent the data hierarchically, through several levels of abstraction corresponding to various artificial perceptrons [17] For this reason, the DL approaches are based on deep neural networks composed of sets of hidden layers: in each step, the input data is transformed into a slightly more abstract and composite one.
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