期刊
BIOMEDICAL SIGNAL PROCESSING AND CONTROL
卷 60, 期 -, 页码 -出版社
ELSEVIER SCI LTD
DOI: 10.1016/j.bspc.2020.101990
关键词
Electroencephalography (EEG); Electromyography (EMG); Fusion; Lower limb; Wireless foot sensor module
资金
- CSIR-Central Scientific Instruments Organisation, Chandigarh research lab, India
Introduction: The study of motor cortex represents the presence of functional activity around mesial surface during all lower limb movements. Due to this, the problem of classification for intricate lower limb movements is particularly challenging with existing non-invasive technologies, such as electroencephalography (EEG). The other bio-signal used for detection i.e. electromyography (EMG), underlines the factors such as muscular fatigue and spasm as possible hindrance for efficient task based classification. Methods: This work aims to explore the fusion of both, EEG and EMG, sensing modules to identify unilateral lower limb movements. Four channel sets were formed with optimal selection of EEG and EMG channels. The processed bio-signals were analyzed for parallel as well as cascaded classification of five tasks. The performance has been assessed using two parameters, prediction accuracy (PA) and computational time (C-T). Results: The approach successfully classified the five tasks with maximum PA of (96.58 +/- 2.37)% and C-T of (51.89 +/- 1.15)ms for cascaded scheme. The optimal performance has been achieved with PA of (90.06 +/- 9.71)% and (89.81 +/- 9.41)% for channel-set (Ch) i.e. 7-Ch and 3-Ch, respectively. The resulting C-T of (52.82 +/- 3.56)ms and (65.38 +/- 3.36)ms have been obtained for 7-Ch and 3-Ch, respectively. The parallel scheme resulted in PA of (85.88 +/- 3.92)% and (86.16 +/- 3.97)% along with C-T of (33.23 +/- 6.74)ms and (34.80 +/- 10.42)ms for 7-Ch and 3-Ch, respectively. Conclusion: The obtained results showed a higher PA for the case of cascaded classification compared to the parallel scheme. Promising results have been achieved, for healthy participants and can be used for future applications of robotic device control and rehabilitation. (C) 2020 Elsevier Ltd. All rights reserved.
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