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Practical method for predicting intended gait speed via soleus surface EMG signals

Authors
Kim, J.Chung, S. H.Choi, J.Lee, J. M.Kim, S-J
Issue Date
28-5월-2020
Publisher
INST ENGINEERING TECHNOLOGY-IET
Keywords
medical robotics; electromyography; patient rehabilitation; regression analysis; gait analysis; medical signal processing; intended gait speed; soleus surface EMG signals; patient effort; robot-assisted gait training; hemiparetic stroke patients; patient-driven RAGT; gait intent; joint movement; step speed intent; surface electromyogram signals; lower-limb muscles; simple linear regression model; over-ground gait sessions; rehabilitative efficacy; soleus EMG signals
Citation
ELECTRONICS LETTERS, v.56, no.11, pp.528 - 530
Indexed
SCIE
SCOPUS
Journal Title
ELECTRONICS LETTERS
Volume
56
Number
11
Start Page
528
End Page
530
URI
https://scholar.korea.ac.kr/handle/2021.sw.korea/55629
DOI
10.1049/el.2020.0090
ISSN
0013-5194
Abstract
The lack of patient effort during robot-assisted gait training (RAGT) is thought to be the main factor behind unsatisfactory rehabilitative efficacy among hemiparetic stroke patients. A key milestone to implement patient-driven RAGT is to predict gait intent prior to actual joint movement. Here, the authors propose a method of predicting step speed intent via surface electromyogram (EMG) signals from the soleus. Six lower-limb muscles were initially evaluated on a treadmill, and the results suggest that the soleus EMG signals correlate well with step speed. The authors further propose a simple linear regression model which predicts subsequent step speed via current soleus EMG signals with over-ground gait sessions, R-2 of similar to 0.6. The proposed experimental results and simple prediction model should be applicable for RAGT without significant modifications.
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