Continuous estimation of ground reaction force during long distance running within a fatigue monitoring framework: A Kalman filter-based model-data fusion approach

• Published in: Journal of biomechanics Vol. 115; p. 110130
• Main Authors: LeBlanc, Benjamin, Hernandez, Eric M., McGinnis, Ryan S., Gurchiek, Reed D.
• Format: Journal Article
• Language: English
• Published: United States Elsevier Ltd 22.01.2021; Elsevier Limited
• Subjects: Acceleration; Algorithms; Biofeedback; Biomechanics; Data integration; Dynamical systems; Feedback; Force plates; Injuries; Kalman filter; Kalman filters; Kinematics; Laboratories; Loading rate; Mathematical models; Minimal instrumentation; Optoelectronics; Parameter estimation; Parameter identification; Running; Sacrum; Sensors; State estimation; Stiffness; System dynamics; Treadmills; Vertical forces; Waveforms; Wearable sensors; Running; Minimal instrumentation; State estimation; Kalman filter; Wearable sensors
• ISSN: 0021-9290; 1873-2380; 1873-2380
• DOI: 10.1016/j.jbiomech.2020.110130

Estimation of ground reaction forces in runners has been limited to laboratory environments by means of instrumented treadmills, in-ground force plates and optoelectronic systems. Recent advances in estimation techniques using wearable sensors for kinematic analysis and sports performance could enable estimation outside the laboratory. This paper proposes a state-input-parameter estimation framework to continuously estimate the vertical ground reaction force waveform during running. By modeling a runner as a single degree of freedom mass-spring-damper with acceleration measurements at the sacrum a state-space formulation can be applied using Newtonian methods. A dual-Kalman filter is employed to estimate the unmeasured system input which feeds through to an unscented Kalman filter to estimate system dynamics and unknown model parameters (e.g. spring stiffness). For validation, 14 subjects performed three one-minute running trials at three different speeds (self-selected slow, comfortable, and fast) on a pressure-sensor-instrumented treadmill. The estimated vertical ground reaction force waveform parameters; peak vertical ground reaction force (RMSE=6.1-7.2%,ρ=0.95-0.97), vertical impulse (RMSE=8.5-13.0%,ρ=0.50-0.60), loading rate (RMSE=24.6-39.4%,ρ=0.85-0.93), and cadence RMSE<1%,ρ=1.00 were compared against the instrumented treadmill measurements. The proposed state-input-parameter estimation framework could monitor personalized vertical ground reaction force metrics for potential biofeedback applications. The feedback mechanism could provide information about the vertical ground reaction force characteristics to the runner as they are running to provide knowledge of both desirable and undesirable loading characteristics experienced.