A Bayesian framework for integrated deep metric learning and tracking of vulnerable road users using automotive radars

With the recent advancements in radar systems, radar sensors offer a promising and effective perception of the surrounding. This includes target detection, classification and tracking. Compared to the state-of-the-art, where the state vector of classical tracker considers only localization parameters, this paper proposes an integrated Bayesian framework by augmenting state vector with feature embedding as appearance parameter together with localization parameter. In context of automotive vulnerable road users (VRUs) such as pedestrian and cyclist, the classical tracker poses multiple challenges to preserve the identity of the tracked target during partial or complete occlusion, due to low inter-class (pedestrian-cyclist) variations and strong similarity between intra-class (pedestrian-pedestrian). Subsequently, feature embedding corresponding to target's micro-Doppler signature are learned using novel Bayesian based deep metric learning approaches. The tracker's performance is optimized due to a better separability of the targets. At the same time, the classifiers' performance is enhanced due to Bayesian formulation utilizing the temporal smoothing of the classifier's embedding vector. In this work, we demonstrate the performance of the proposed Bayesian framework using several vulnerable user targets based on a 77 GHz automotive radar.

Subjects

Automotive radar

Bayesian framework

deep metric learning

integrated classification-tracking

unscented Kalman filter

DDC Class

600: Technik

Publication version

publishedVersion

Lizenz

https://creativecommons.org/licenses/by/4.0/

Name

A_Bayesian_Framework_for_Integrated_Deep_Metric_Learning_and_Tracking_of_Vulnerable_Road_Users_Using_Automotive_Radars.pdf

Size

4.4 MB

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Adobe PDF

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A Bayesian framework for integrated deep metric learning and tracking of vulnerable road users using automotive radars