Abstract
Artificial neural networks were satisfactorily implemented for assessing gait events from different walking data. This study aims to propose a novel approach for recognizing gait phases and events, based on deep-learning analysis of only sagittal knee-joint angle measured by a single electrogoniometer per leg. Promising classification/prediction performances have been previously achieved by surface-EMG studies; thus, a further aim is to test if adding electrogoniometer data could improve classification performances of state-of-the-art methods. Gait data are measured in about 10,000 strides from 23 healthy adults, during ground walking. A multi-layer perceptron model is implemented, composed of three hidden layers and a one-dimensional output. Classification/prediction accuracy is tested vs. ground truth represented by foot–floor-contact signals, through samples acquired from subjects not seen during training phase. Average classification-accuracy of 90.6 ± 2.9% and mean absolute value (MAE) of 29.4 ± 13.7 and 99.5 ± 28.9 ms in assessing heel-strike and toe-off timing are achieved in unseen subjects. Improvement of classification-accuracy (four points) and reduction of MAE (at least 35%) are achieved when knee-angle data are used to enhance sEMG-data prediction. Comparison of the two approaches shows as the reduction of set-up complexity implies a worsening of mainly toe-off prediction. Thus, the present electrogoniometer approach is particularly suitable for the classification tasks where only heel-strike event is involved, such as stride recognition, stride-time computation, and identification of toe walking.
Highlights
Modifications of motor function associated to different environments or state of health are typically estimated and quantified by means of instrumental gait analysis
Average classification accuracies in every fold for the Knee, KEMG, and Reference approaches are shown in Table 1 for the learned-test set (LS-test) and in Table 2 for unlearned set (US)
The goal of this study is to propose a novel approach for classifying stance vs. swing and assessing heel strike (HS) and toe off (TO) timing, based on deep learning analysis of sagittal knee-angle data measured with a single electrogoniometer per each leg
Summary
Modifications of motor function associated to different environments or state of health are typically estimated and quantified by means of instrumental gait analysis. To this aim, relevant seems to be the problem of recognizing at least the two main gait phases, namely stance and swing. The problem of estimating temporal parameters of gait could take great advantage by the development of these new approaches. The use of IMUs appears to be suitable for a smart assessment of walking parameters, such as gait-phase duration and timing of heel strike (time when the foot touches the ground) and toe off
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