Supervised learning for improving the accuracy of robot-mounted 3D camera applied to human gait analysis

Diego Guffanti; Alberto Brunete; Miguel Hernando; David Álvarez; Javier Rueda; Enrique Navarro

doi:10.1016/j.heliyon.2024.e26227

Supervised learning for improving the accuracy of robot-mounted 3D camera applied to human gait analysis

Heliyon. 2024 Feb 13;10(4):e26227. doi: 10.1016/j.heliyon.2024.e26227. eCollection 2024 Feb 29.

Authors

Diego Guffanti^{1

2}, Alberto Brunete³, Miguel Hernando³, David Álvarez⁴, Javier Rueda⁵, Enrique Navarro⁵

Affiliations

¹ Centro de Investigación en Mecatrónica y Sistemas Interactivos - MIST, Universidad Indoamérica, Av. Machala y Sabanilla, 170103, Quito, Ecuador.
² Universidad UTE, Av. Mariscal Sucre, Quito, 170129, Ecuador.
³ Centre for Automation and Robotics (CAR UPM-CSIC), Universidad Politécnica de Madrid, 28012 Madrid, Spain.
⁴ Department of Electrical, Electronic and Automation Engineering and Applied Physics, ETSIDI, Universidad Politécnica de Madrid, 28012 Madrid, Spain.
⁵ Department of Human Health and Performance, Faculty of Sports Sciences, Universidad Politécnica de Madrid, 28040 Madrid, Spain.

Abstract

Background and objective: the use of 3D cameras for gait analysis has been highly questioned due to the low accuracy they have demonstrated in the past. The objective of the study presented in this paper is to improve the accuracy of the estimations made by robot-mounted 3D cameras in human gait analysis by applying a supervised learning stage.

Methods: the 3D camera was mounted in a mobile robot to obtain a longer walking distance. This study shows an improvement in detection of kinematic gait signals and gait descriptors by post-processing the raw estimations of the camera using artificial neural networks trained with the data obtained from a certified Vicon system. To achieve this, 37 healthy participants were recruited and data of 207 gait sequences were collected using an Orbbec Astra 3D camera. There are two basic possible approaches for training and both have been studied in order to see which one achieves a better result. The artificial neural network can be trained either to obtain more accurate kinematic gait signals or to improve the gait descriptors obtained after initial processing. The former seeks to improve the waveforms of kinematic gait signals by reducing the error and increasing the correlation with respect to the Vicon system. The second is a more direct approach, focusing on training the artificial neural networks using gait descriptors directly.

Results: the accuracy of the 3D camera to objectify human gait was measured before and after training. In both training approaches, a considerable improvement was observed. Kinematic gait signals showed lower errors and higher correlations with respect to the ground truth. The accuracy of the system to detect gait descriptors also showed a substantial improvement, mostly for kinematic descriptors rather than spatio-temporal. When comparing both training approaches, it was not possible to define which was the absolute best.

Conclusions: supervised learning improves the accuracy of 3D cameras but the selection of the training approach will depend on the purpose of the study to be conducted. This study reveals the great potential of 3D cameras and encourages the research community to continue exploring their use in gait analysis.

Keywords: 3D camera; Gait analysis; Machine learning; Mobile robot.