Abstract
In the field of lower limb exoskeletons, besides its electromechanical system design and control, attention has been paid to realizing the linkage of exoskeleton robots to humans via electroencephalography (EEG) and electromyography (EMG). However, even the state of the art performance of lower limb voluntary movement intention decoding still faces many obstacles. In the following work, focusing on the perspective of the inner mechanism, a homology characteristic of EEG and EMG for lower limb voluntary movement intention was conducted. A mathematical model of EEG and EMG was built based on its mechanism, which consists of a neural mass model (NMM), neuromuscular junction model, EMG generation model, decoding model, and musculoskeletal biomechanical model. The mechanism analysis and simulation results demonstrated that EEG and EMG signals were both excited by the same movement intention with a response time difference. To assess the efficiency of the proposed model, a synchronous acquisition system for EEG and EMG was constructed to analyze the homology and response time difference from EEG and EMG signals in the limb movement intention. An effective method of wavelet coherence was used to analyze the internal correlation between EEG and EMG signals in the same limb movement intention. To further prove the effectiveness of the hypothesis in this paper, six subjects were involved in the experiments. The experimental results demonstrated that there was a strong EEG-EMG coherence at 1 Hz around movement onset, and the phase of EEG was leading the EMG. Both the simulation and experimental results revealed that EEG and EMG are homologous, and the response time of the EEG signals are earlier than EMG signals during the limb movement intention. This work can provide a theoretical basis for the feasibility of EEG-based pre-perception and fusion perception of EEG and EMG in human movement detection.
Highlights
With the intensifying of the aging problem, and with the military and civilian goals to amplify the human ability, many studies have focused on the development of robotics to break through human motor limitations such as terrain conditions or individual ability (Al-Quraishi et al, 2018)
The mathematical model of EEG and EMG from lower limb voluntary movement intention was proposed based on the electrophysiological analysis, which revealed the mechanism of EEG and EMG signals and the homology of those two signals
The internal relationship between EEG and EMG has a clear exposition, from which the difference in response time has been shown from the transmission pathway in this model
Summary
With the intensifying of the aging problem, and with the military and civilian goals to amplify the human ability, many studies have focused on the development of robotics to break through human motor limitations such as terrain conditions or individual ability (Al-Quraishi et al, 2018). Besides the assistive tool for healthy people, lower limb exoskeleton robotics is expected to broadly meet social requirements in the fields of medical treatment, walking-assistance for senior and disabled people, industrial and agricultural production, and other fields (Rupal et al, 2017). Despite this field having attracted a considerable level of attention over the last few years, there are still some problems with the prediction of human lower limb voluntary movement intention (Chen et al, 2016). Several efforts have been made to apply EEG and EMG for robotic control, since it can solve this problem very well
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