Posture Estimation of Curve Running Motion Using Nano-Biosensor and Machine Learning

Xiaoming Wu; Yu Cao; Yu Wang; Bing Li; Haitao Yang; S. P. Raja

doi:10.9781/ijimai.2024.07.001

Authors

Xiaoming Wu Capital Normal University
Yu Cao Renmin University of China
Yu Wang Capital Normal University
Bing Li Harbin Sport University (China)
Haitao Yang Beijing University of Technology
S. P. Raja Vellore Institute of Technology University

DOI:

https://doi.org/10.9781/ijimai.2024.07.001

Keywords:

Curve Running Motion, Machine Learning, Nano-Biosensor, Posture Angle, Posture Estimation

Abstract

Curve running is a common form of training and competition. Conducting research on posture estimation during curve running can provide more accurate training and competition data for athletes. However, due to the unique nature of curve running, traditional posture estimation methods neglect the temporal changes in athlete posture, resulting in a decrease in estimation accuracy. Therefore, a posture estimation method for curve running motion using nano-biosensor and machine learning is proposed. First, the motion parameters of humans are collected by nano-biosensor, and the posture coordinates are obtained preliminarily. Second, the posture coordinates are established according to the human motion parameters, and the curve running posture data is obtained and filtered to obtain more accurate data. Finally, the Bayesian network in machine learning is used to continuously track the posture, and a nonlinear equation is established to fuse the posture angle obtained by the sensor and the posture tracked by the Bayesian network, to realize the posture estimation of curve running motion. The results show that the proposed estimation method has a good motion posture estimation effect, and the hip joint estimation error, knee joint estimation error and ankle joint estimation error are all less than 5°, and the endpoint displacement estimation offset rate is less than 2%. It can realize accurate motion posture estimation of curve running motion, and has important application value in the field of track training.

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