Predicting athlete ground reaction forces and moments from motion capture
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Mian, Ajmal
Donnelly, Cyril J
Lloyd, David
Alderson, Jacqueline
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Abstract
An understanding of athlete ground reaction forces and moments (GRF/Ms) facilitates the biomechanist’s downstream calculation of net joint forces and moments, and associated injury risk. Historically, force platforms used to collect kinetic data are housed within laboratory settings and are not suitable for field-based installation. Given that Newton’s Second Law clearly describes the relationship between a body’s mass, acceleration, and resultant force, is it possible that marker-based motion capture can represent these parameters sufficiently enough to estimate GRF/Ms, and thereby minimize our reliance on surface embedded force platforms? Specifically, can we successfully use partial least squares (PLS) regression to learn the relationship between motion capture and GRF/Ms data? In total, we analyzed 11 PLS methods and achieved average correlation coefficients of 0.9804 for GRFs and 0.9143 for GRMs. Our results demonstrate the feasibility of predicting accurate GRF/Ms from raw motion capture trajectories in real-time, overcoming what has been a significant barrier to non-invasive collection of such data. In applied biomechanics research, this outcome has the potential to revolutionize athlete performance enhancement and injury prevention.
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Medical and Biological Engineering and Computing
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56
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10
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© 2018 Springer Berlin / Heidelberg. This is an electronic version of an article published in Medical and Biological Engineering and Computing, Vol.56(10):1781-1792, 2018. Medical and Biological Engineering and Computing is available online at: http://link.springer.com/ with the open https://doi.org/10.1007/s11517-018-1802-7 of your article.
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Biomedical engineering
Biomedical engineering not elsewhere classified
Electronics, sensors and digital hardware
Action recognition
Wearable sensors
Computer simulation