OBJECTIVE: The foot progression angle (FPA) is an important clinical measurement but currently can only be computed while walking in a laboratory with a marker-based motion capture system. This paper proposes a novel FPA estimation algorithm based on a single integrated sensor unit, consisting of an accelerometer, gyroscope, and magnetometer, worn on the foot. METHODS: The algorithm introduces a real-time heading vector with a complementary filter and utilizes a gradient descent method and zero-velocity update correction. Validation testing was performed by comparing FPA estimation from the wearable sensor with the standard FPAs computed from a marker-based motion capture system. Subjects performed nine walking trials of 2.5 min each on a treadmill. During each trial, subjects walked at one speed out of three options (1.0, 1.2, and 1.4 m/s) and walked with one gait pattern out of three options (normal, toe-in, and toe-out). RESULTS: The algorithm estimated FPA to within 0.2 ° of error or less for each walking conditions. CONCLUSION: A novel FPA algorithm has been introduced and described based on a single foot-worn sensor unit, and validation testing showed that FPA estimation was accurate for different walking speeds and foot angles. SIGNIFICANCE: This study enables future wearable systems gait research to assess or train walking patterns outside a laboratory setting in natural walking environments.
OBJECTIVE: The foot progression angle (FPA) is an important clinical measurement but currently can only be computed while walking in a laboratory with a marker-based motion capture system. This paper proposes a novel FPA estimation algorithm based on a single integrated sensor unit, consisting of an accelerometer, gyroscope, and magnetometer, worn on the foot. METHODS: The algorithm introduces a real-time heading vector with a complementary filter and utilizes a gradient descent method and zero-velocity update correction. Validation testing was performed by comparing FPA estimation from the wearable sensor with the standard FPAs computed from a marker-based motion capture system. Subjects performed nine walking trials of 2.5 min each on a treadmill. During each trial, subjects walked at one speed out of three options (1.0, 1.2, and 1.4 m/s) and walked with one gait pattern out of three options (normal, toe-in, and toe-out). RESULTS: The algorithm estimated FPA to within 0.2 ° of error or less for each walking conditions. CONCLUSION: A novel FPA algorithm has been introduced and described based on a single foot-worn sensor unit, and validation testing showed that FPA estimation was accurate for different walking speeds and foot angles. SIGNIFICANCE: This study enables future wearable systems gait research to assess or train walking patterns outside a laboratory setting in natural walking environments.
Authors: Angelos Karatsidis; Rosie E Richards; Jason M Konrath; Josien C van den Noort; H Martin Schepers; Giovanni Bellusci; Jaap Harlaar; Peter H Veltink Journal: J Neuroeng Rehabil Date: 2018-08-15 Impact factor: 4.262
Authors: Frank J Wouda; Stephan L J O Jaspar; Jaap Harlaar; Bert-Jan F van Beijnum; Peter H Veltink Journal: J Neuroeng Rehabil Date: 2021-02-17 Impact factor: 4.262
Authors: Dylan Kobsar; Jesse M Charlton; Calvin T F Tse; Jean-Francois Esculier; Angelo Graffos; Natasha M Krowchuk; Daniel Thatcher; Michael A Hunt Journal: J Neuroeng Rehabil Date: 2020-05-11 Impact factor: 4.262