Abstract
The main goal of this research is to develop a control strategy for an underactuated robotic hand, based on surface electromyography (sEMG) signal obtained from a wireless Myo gesture armband, to distinguish six, several hand movements. The pattern recognition system is employed to analyze these gestures and consists of three main parts: segmentation, feature extraction, and classification. A series of 150 trials is carried out for each movement and it is established which was most suitable for electromyography signals that can be later used in recognition systems. A backpropagation neural network was used as a classifier. The architecture has a hidden network and six output layers. The number of neurons of the hidden network (20) was determined based on the performance in training progress. The proposed system is tested on datasets extracted from five healthy subjects. A great accuracy (94.94% correct assessment). between the experimentally values and those predicted by the artificial neural network (ANN) was achieved. In addition, kinematic analysis of the proposed underactuated hand has been carried out to verify the motion range of the joints. Simulations and experiments are carried out to verify the effectiveness of the proposed fingers mechanism and the hand prosthesis to generate grasp or postures.
Highlights
Due to its use in majority of activities of daily living (ADL), the human hand is one of the most essential body parts, which enables humans to perform basic daily activities ranging from hand gestures to object manipulation [1]
High-performance prosthetic hands significantly improve the quality of life for upper limb amputees
3.1 Pattern recognition system Feature extraction was carried out with each posture using the series of time domain, and processing with the Matlab software for six motions or positions of the hand
Summary
Due to its use in majority of activities of daily living (ADL), the human hand is one of the most essential body parts, which enables humans to perform basic daily activities ranging from hand gestures to object manipulation [1]. Amputation results from accidents at work, armed conflicts, diseases, and malformations [2], Biosensors - Current and Novel Strategies for Biosensing and it is a severe mental and physical trauma with the loss of both motor and sensory perceptions [3]. High-performance prosthetic hands significantly improve the quality of life for upper limb amputees. Passive prosthetic hands are lightweight, robust, and quiet but can only perform a limited subset of activities. Researchers have investigated externally powered prosthetic hands for upper limb amputees for more than a century. These devices, which emulate with human hand, are characterized by complex systems based on microprocessor technology
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