Journal
IEEE ACCESS
Volume 7, Issue -, Pages 156779-156786Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/ACCESS.2019.2949699
Keywords
Training; Neurons; Artificial neural networks; Kinematics; Force; Acceleration; Biomechanics; Accelerometry; artificial neural networks; human biomechanics; motion analysis; kinematics; sports performance
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Funding
- Enterprise Ireland [IP 2017 0606]
- Setanta College Ltd. [IP 2017 0606]
- European Regional Development Fund (ERDF) through the Ireland's European Structural and Investment Funds Programmes 2014-2020
- Science Foundation Ireland - European Regional Development Fund [12/RC/2289-P2]
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This study explored the use of artificial neural networks in the estimation of runners kinetics from lower body kinematics. Three supervised feed-forward artificial neural networks with one hidden layer each were modelled and assigned individually with the mapping of a single force component. Number of training epochs, batch size and dropout rate were treated as modelling hyper-parameters and their values were optimised with a grid search. A public data set of twenty-eight professional athletes containing running trails of different speeds (2.5 m/sec, 3.5 m/sec and 4.5 m/sec) was employed to train and validate the networks. Movements of the lower limbs were captured with twelve motion capture cameras and an instrumented dual-belt treadmill. The acceleration of the shanks was fed to the artificial neural networks and the estimated forces were compared to the kinetic recordings of the instrumented treadmill. Root mean square error was used to evaluate the performance of the models. Predictions were accompanied with low errors: 0.134 BW for the vertical, 0.041 BW for the anteroposterior and 0.042 BW for the mediolateral component of the force. Vertical and anteroposterior estimates were independent of running speed (p0.233 and p.058, respectively), while mediolateral results were significantly more accurate for low running speeds (p0.010). The maximum force mean error between measured and estimated values was found during the vertical active peak (0.114 0.088 BW). Findings indicate that artificial neural networks in conjunction with accelerometry may be used to compute three-dimensional ground reaction forces in running.
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