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Development and validation of a neural network for adaptive gait cycle detection from kinematic data

  • (1) Background: Instrumented gait analysis is a tool for quantification of the different aspects of the locomotor system. Gait analysis technology has substantially evolved over the last decade and most modern systems provide real-time capability. The ability to calculate joint angles with low delays paves the way for new applications such as real-time movement feedback, like control of functional electrical stimulation in the rehabilitation of individuals with gait disorders. For any kind of therapeutic application, the timely determination of different gait phases such as stance or swing is crucial. Gait phases are usually estimated based on heuristics of joint angles or time points of certain gait events. Such heuristic approaches often do not work properly in people with gait disorders due to the greater variability of their pathological gait pattern. To improve the current state-ofthe- art, this thesis aims to introduce a data-driven approach for real-time determination of gait phases from kinematic variables based on long short-term memory recurrent neural networks (LSTM RNNs). (2) Methods: In this thesis, 56 measurements with gait data of 11 healthy subjects, 13 individuals with incomplete spinal cord injury and 10 stroke survivors with walking speeds ranging from 0.2 m s up to 1 m s were used to train the networks. Each measurement contained kinematic data from the corresponding subject walking on a treadmill for 90 seconds. Kinematic data was obtained by measuring the positions of reflective markers on body landmarks (Helen Hayes marker set) with a sample rate of 60Hz. For constructing a ground truth, gait data was annotated manually by three raters. Two approaches, direct regression of gait phases and estimation via detection of the gait events Initial Contact and Final Contact were implemented for evaluation of the performance of LSTM RNNs. For comparison of performance, the frequently cited coordinate- and velocity-based event detection approaches of Zeni et al. were used. All aspects of this thesis have been implemented within MATLAB Version 9.6 using the Deep Learning Toolbox. (3) Results: The mean time difference between events annotated by the three raters was −0.07 ± 20.17ms. Correlation coefficients of inter-rater and intra-rater reliability yielded mainly excellent or perfect results. For detection of gait events, the LSTM RNN algorithm covered 97.05% of all events within a scope of 50ms. The overall mean time difference between detected events and ground truth was −11.62 ± 7.01ms. Temporal differences and deviations were consistently small over different walking speeds and gait pathologies. Mean time difference to the ground truth was 13.61 ± 17.88ms for the coordinate-based approach of Zeni et al. and 17.18 ± 15.67ms for the velocity-based approach. For estimation of gait phases, the gait phase was determined as a percentage. Mean squared error to the ground truth was 0.95 ± 0.55% for the proposed algorithm using event detection and 1.50 ± 0.55% for regression. For the approaches of Zeni et al., mean squared error was 2.04±1.23% for the coordinate-based approach and 2.24±1.34% for the velocity-based approach. Regarding mean absolute error to the ground truth, the proposed algorithm achieved a mean absolute error of 1.95±1.10% using event detection and one of 7.25 ± 1.45% using regression. Mean absolute error for the coordinate-based approach of Zeni et al. was 4.08±2.51% and 4.50±2.73% for the velocity-based approach. (4) Conclusion: The newly introduced LSTM RNN algorithm offers a high recognition rate of gait events with a small delay. Its performance outperforms several state-of-theart gait event detection methods while offering the possibility for real-time processing and high generalization of trained gait patterns. Additionally, the proposed algorithm is easy to integrate into existing applications and contains parameters that self-adapt to individuals’ gait behavior to further improve performance. In respect to gait phase estimation, the performance of the proposed algorithm using event detection is in line with current wearable state-of-the-art methods. Compared with conventional methods, performance of direct regression of gait phases is only moderate. Given the results, LSTM RNNs demonstrate feasibility regarding event detection and are applicable for many clinical and research applications. They may be not suitable for the estimation of gait phases via regression. For LSTM RNNs, it can be assumed, that with a more optimal configuration of the networks, a much higher performance is achieved.

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Metadaten
Author:Alexander Kombeiz
URN:urn:nbn:de:bsz:840-opus4-1742
Referee:Rüdiger Rupp
Advisor:Christoph Maier
Document Type:Master's Thesis
Language:English
Year of Completion:2020
Publishing Institution:Hochschule Heilbronn
Granting Institution:Hochschule Heilbronn
Date of final exam:2020/01/21
Release Date:2020/02/17
Tag:Gangzyklus-Erkennung; Kinematik
GND Keyword:Neuronales Netz
Pagenumber:XIII, 63 Seiten
Faculty:Informatik
DDC classes:500 Naturwissenschaften und Mathematik
600 Technik, Medizin, angewandte Wissenschaften
Access Right:Frei zugänglich
Licence (German):License LogoCreative Commons - CC BY-NC-ND - Namensnennung - Nicht kommerziell - Keine Bearbeitungen 4.0 International