Technology for Improving the Accuracy of Predicting the Position and Speed of Human Movement Based on Machine Learning Models

Technology for Improving the Accuracy of Predicting the Position and Speed of Human Movement Based on Machine Learning Models

The solution to the problem of insufficient accuracy in determining the position and speed of human movement during interaction with a treadmill-based training complex is considered. Control command generation based on the training complex user’s actions may be performed with a delay, may not take i...

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Bibliographic Details
Main Authors: Artem Obukhov, Denis Dedov, Andrey Volkov, Maksim Rybachok
Format: Article
Language:English
Published: MDPI AG 2025-03-01
Series:Technologies
Subjects:
machine learning
neural networks
computer vision
speed prediction
human movement analysis
running platforms
Online Access:https://www.mdpi.com/2227-7080/13/3/101
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Summary:The solution to the problem of insufficient accuracy in determining the position and speed of human movement during interaction with a treadmill-based training complex is considered. Control command generation based on the training complex user’s actions may be performed with a delay, may not take into account the specificity of movements, or be inaccurate due to the error of the initial data. The article introduces a technology for improving the accuracy of predicting a person’s position and speed on a running platform using machine learning and computer vision methods. The proposed technology includes analysing and processing data from the tracking system, developing machine learning models to improve the quality of the raw data, predicting the position and speed of human movement, and implementing and integrating neural network methods into the running platform control system. Experimental results demonstrate that the decision tree (DT) model provides better accuracy and performance in solving the problem of positioning key points of a human model in complex conditions with overlapping limbs. For speed prediction, the linear regression (LR) model showed the best results when the analysed window length was 10 frames. Prediction of the person’s position (based on 10 previous frames) is performed using the DT model, which is optimal in terms of accuracy and computation time relative to other options. The comparison of the control methods of the running platform based on machine learning models showed the advantage of the combined method (linear control function combined with the speed prediction model), which provides an average absolute error value of 0.116 m/s. The results of the research confirmed the achievement of the primary objective (increasing the accuracy of human position and speed prediction), making the proposed technology promising for application in human-machine systems.
ISSN:2227-7080

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