English

Interpretable Gait Recognition by Granger Causality

Computer Vision and Pattern Recognition 2022-12-09 v3

Abstract

Which joint interactions in the human gait cycle can be used as biometric characteristics? Most current methods on gait recognition suffer from the lack of interpretability. We propose an interpretable feature representation of gait sequences by the graphical Granger causal inference. Gait sequence of a person in the standardized motion capture format, constituting a set of 3D joint spatial trajectories, is envisaged as a causal system of joints interacting in time. We apply the graphical Granger model (GGM) to obtain the so-called Granger causal graph among joints as a discriminative and visually interpretable representation of a person's gait. We evaluate eleven distance functions in the GGM feature space by established classification and class-separability evaluation metrics. Our experiments indicate that, depending on the metric, the most appropriate distance functions for the GGM are the total norm distance and the Ky-Fan 1-norm distance. Experiments also show that the GGM is able to detect the most discriminative joint interactions and that it outperforms five related interpretable models in correct classification rate and in Davies-Bouldin index. The proposed GGM model can serve as a complementary tool for gait analysis in kinesiology or for gait recognition in video surveillance.

Keywords

Cite

@article{arxiv.2206.06714,
  title  = {Interpretable Gait Recognition by Granger Causality},
  author = {Michal Balazia and Katerina Hlavackova-Schindler and Petr Sojka and Claudia Plant},
  journal= {arXiv preprint arXiv:2206.06714},
  year   = {2022}
}

Comments

Preprint. Full paper accepted at the IEEE/IAPR International Conference on Pattern Recognition (ICPR), Montreal, Canada, August 2022. 7 pages

R2 v1 2026-06-24T11:50:30.307Z