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Calibration-Free Gait Assessment by Foot-Worn Inertial Sensors

Daniel Laidig, Andreas J. Jocham, Bernhard Guggenberger, Klemens Adamer, Michael J. Fischer, Thomas Seel

2021Frontiers in Digital Health32 citationsDOIOpen Access PDF

Abstract

Walking is a central activity of daily life, and there is an increasing demand for objective measurement-based gait assessment. In contrast to stationary systems, wearable inertial measurement units (IMUs) have the potential to enable non-restrictive and accurate gait assessment in daily life. We propose a set of algorithms that uses the measurements of two foot-worn IMUs to determine major spatiotemporal gait parameters that are essential for clinical gait assessment: durations of five gait phases for each side as well as stride length, walking speed, and cadence. Compared to many existing methods, the proposed algorithms neither require magnetometers nor a precise mounting of the sensor or dedicated calibration movements. They are therefore suitable for unsupervised use by non-experts in indoor as well as outdoor environments. While previously proposed methods are rarely validated in pathological gait, we evaluate the accuracy of the proposed algorithms on a very broad dataset consisting of 215 trials and three different subject groups walking on a treadmill: healthy subjects ( n = 39), walking at three different speeds, as well as orthopedic ( n = 62) and neurological ( n = 36) patients, walking at a self-selected speed. The results show a very strong correlation of all gait parameters (Pearson's r between 0.83 and 0.99, p < 0.01) between the IMU system and the reference system. The mean absolute difference (MAD) is 1.4 % for the gait phase durations, 1.7 cm for the stride length, 0.04 km/h for the walking speed, and 0.7 steps/min for the cadence. We show that the proposed methods achieve high accuracy not only for a large range of walking speeds but also in pathological gait as it occurs in orthopedic and neurological diseases. In contrast to all previous research, we present calibration-free methods for the estimation of gait phases and spatiotemporal parameters and validate them in a large number of patients with different pathologies. The proposed methods lay the foundation for ubiquitous unsupervised gait assessment in daily-life environments.

Topics & Concepts

GaitSTRIDEInertial measurement unitCadenceUnits of measurementPhysical medicine and rehabilitationGait analysisPreferred walking speedWearable computerComputer scienceAccelerometerTreadmillCalibrationPower walkingEffect of gait parameters on energetic costSimulationArtificial intelligencePhysical therapyMathematicsMedicineStatisticsOperating systemPhysicsQuantum mechanicsEmbedded systemBalance, Gait, and Falls PreventionDiabetic Foot Ulcer Assessment and ManagementLower Extremity Biomechanics and Pathologies
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