Abstract
Surface electromyographic (sEMG) signals are weak physiological electrical signals, which are highly susceptible to coupling external noise and cause major difficulties in signal acquisition and processing. The study of using sEMG signals to analyze human motion intention mainly involves data preprocessing, feature extraction, and model classification. Feature extraction is an extremely critical part; however, this often involves many manually designed features with specialized domain knowledge, so the experimenter will spend time and effort on feature extraction. To address this problem, deep learning methods that can automatically extract features are applied to the sEMG-based gesture recognition problem, drawing on the success of deep learning for image classification. In this paper, sEMG is captured using a wearable, flexible bionic device, which is simple to operate and highly secure. A multi-stream convolutional neural network algorithm is proposed to enhance the ability of sEMG to characterize hand actions in gesture recognition. The algorithm virtually augments the signal channels by reconstructing the sample structure of the sEMG to provide richer input information for gesture recognition. The methods for noise processing, active segment detection, and feature extraction are investigated, and a basic method for gesture recognition based on the combination of multichannel sEMG signals and inertial signals is proposed. Suitable filters are designed for the common noise in the signal. An improved moving average method based on the valve domain is used to reduce the segmentation error rate caused by the short resting signal time in continuous gesture signals. In this paper, three machine learning algorithms, K-nearest neighbor, linear discriminant method, and multi-stream convolutional neural network, are used for hand action classification experiments, and the effectiveness of the multi-stream convolutional neural network algorithm is demonstrated by comparison of the results. To improve the accuracy of hand action recognition, a final 10 gesture classification accuracy of up to 93.69% was obtained. The separability analysis showed significant differences in the signals of the two cognitive-behavioral tasks when the optimal electrode combination was used. A cross-subject analysis of the test set subjects illustrated that the average correct classification rate using the pervasive electrode combination could reach 93.18%.
Highlights
In human structure, hands are the most sensitive limb parts, which can sensitively perceive external things and feedback the information touched to the higher nerve center to make timely and precise action responses
EMG is generated by action potentials generated in the motor cortex of the brain that is transmitted through the spinal cord and peripheral nervous system to reach the muscle fibers, which are low-pass filtered by the skin and form an electrical potential field at the surface (Cao and Liu, 2019)
All three models proposed in this paper can better improve the recognition accuracy of surface electromyographic (sEMG) signals, among which the dual-flow network model that can extract spatiotemporal features of sEMG signals has the best performance and can better distinguish the differences of similar gestures, which has certain research value, and this structure of using a convolutional neural network (CNN) to extract spatial features and using long and short time memory machine to extract spatial features can be used as a researcher in the same field of reference direction
Summary
Hands are the most sensitive limb parts, which can sensitively perceive external things and feedback the information touched to the higher nerve center to make timely and precise action responses. Issues such as how to improve the quality of life of the physically disabled group and enhance the convenience of patients’ lives have received attention from all occupations (Chen et al, 2021a). Most of the commercially available prostheses are designed according to mechatronics This design can meet the basic needs of patients and assist them in simple grasping movements, there are still many problems to be solved, such as the patient cannot naturally control the prosthesis and can only perform a very small part of the functions of the human hand. Gesture recognition based on sEMG signals is one of the important ways to realize such perceptual user interfaces
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