Litcius/Paper detail

Predicting continuous ground reaction forces from accelerometers during uphill and downhill running: a recurrent neural network solution

Ryan S. Alcantara, W. Brent Edwards, Guillaume Y. Millet, Alena M. Grabowski

2022PeerJ73 citationsDOIOpen Access PDF

Abstract

BACKGROUND: Ground reaction forces (GRFs) are important for understanding human movement, but their measurement is generally limited to a laboratory environment. Previous studies have used neural networks to predict GRF waveforms during running from wearable device data, but these predictions are limited to the stance phase of level-ground running. A method of predicting the normal (perpendicular to running surface) GRF waveform using wearable devices across a range of running speeds and slopes could allow researchers and clinicians to predict kinetic and kinematic variables outside the laboratory environment. PURPOSE: We sought to develop a recurrent neural network capable of predicting continuous normal (perpendicular to surface) GRFs across a range of running speeds and slopes from accelerometer data. METHODS: Nineteen subjects ran on a force-measuring treadmill at five slopes (0°, ±5°, ±10°) and three speeds (2.5, 3.33, 4.17 m/s) per slope with sacral- and shoe-mounted accelerometers. We then trained a recurrent neural network to predict normal GRF waveforms frame-by-frame. The predicted versus measured GRF waveforms had an average ± SD RMSE of 0.16 ± 0.04 BW and relative RMSE of 6.4 ± 1.5% across all conditions and subjects. RESULTS: The recurrent neural network predicted continuous normal GRF waveforms across a range of running speeds and slopes with greater accuracy than neural networks implemented in previous studies. This approach may facilitate predictions of biomechanical variables outside the laboratory in near real-time and improves the accuracy of quantifying and monitoring external forces experienced by the body when running.

Topics & Concepts

Ground reaction forceAccelerometerArtificial neural networkKinematicsWaveformSimulationTreadmillWearable computerMean squared errorComputer scienceRange (aeronautics)MathematicsEngineeringArtificial intelligenceStatisticsPhysicsMedicinePhysical therapyTelecommunicationsClassical mechanicsEmbedded systemRadarOperating systemAerospace engineeringLower Extremity Biomechanics and PathologiesSports Performance and TrainingBalance, Gait, and Falls Prevention
Predicting continuous ground reaction forces from accelerometers during uphill and downhill running: a recurrent neural network solution | Litcius