Abstract

There is a need within human movement sciences for a markerless motion capture system, which is easy to use and sufficiently accurate to evaluate motor performance. This study aims to develop a 3D markerless motion capture technique, using OpenPose with multiple synchronized video cameras, and examine its accuracy in comparison with optical marker-based motion capture. Participants performed three motor tasks (walking, countermovement jumping, and ball throwing), and these movements measured using both marker-based optical motion capture and OpenPose-based markerless motion capture. The differences in corresponding joint positions, estimated from the two different methods throughout the analysis, were presented as a mean absolute error (MAE). The results demonstrated that, qualitatively, 3D pose estimation using markerless motion capture could correctly reproduce the movements of participants. Quantitatively, of all the mean absolute errors calculated, approximately 47% were <20 mm, and 80% were <30 mm. However, 10% were >40 mm. The primary reason for mean absolute errors exceeding 40 mm was that OpenPose failed to track the participant's pose in 2D images owing to failures, such as recognition of an object as a human body segment or replacing one segment with another depending on the image of each frame. In conclusion, this study demonstrates that, if an algorithm that corrects all apparently wrong tracking can be incorporated into the system, OpenPose-based markerless motion capture can be used for human movement science with an accuracy of 30 mm or less.

Highlights

  • Motion capture systems have been used extensively as a fundamental technology within biomechanics research

  • It is desirable to many biomechanics researchers to develop a markerless motion capture that is easy to use for measurement

  • This study aimed to examine the accuracy of 3D markerless motion capture using OpenPose with multiple video cameras through comparison with an optical marker-based motion capture

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Summary

Introduction

Motion capture systems have been used extensively as a fundamental technology within biomechanics research. Traditional marker-based approaches have significant environmental constraints. Measurements cannot be performed in environments wherein wearing markers during the activity is difficult (such as sporting games). Markerless measurements without such environmental constraints can facilitate new understanding about human movements (Mündermann et al, 2006); complex information processing technology is required to make an algorithm that recognizes human poses or skeletons from images. It is desirable to many biomechanics researchers to develop a markerless motion capture that is easy to use for measurement

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