Abstract
Natural control methods based on surface electromyography (sEMG) and pattern recognition are promising for hand prosthetics. However, the control robustness offered by scientific research is still not sufficient for many real life applications, and commercial prostheses are capable of offering natural control for only a few movements. In recent years deep learning revolutionized several fields of machine learning, including computer vision and speech recognition. Our objective is to test its methods for natural control of robotic hands via sEMG using a large number of intact subjects and amputees. We tested convolutional networks for the classification of an average of 50 hand movements in 67 intact subjects and 11 transradial amputees. The simple architecture of the neural network allowed to make several tests in order to evaluate the effect of pre-processing, layer architecture, data augmentation and optimization. The classification results are compared with a set of classical classification methods applied on the same datasets. The classification accuracy obtained with convolutional neural networks using the proposed architecture is higher than the average results obtained with the classical classification methods, but lower than the results obtained with the best reference methods in our tests. The results show that convolutional neural networks with a very simple architecture can produce accurate results comparable to the average classical classification methods. They show that several factors (including pre-processing, the architecture of the net and the optimization parameters) can be fundamental for the analysis of sEMG data. Larger networks can achieve higher accuracy on computer vision and object recognition tasks. This fact suggests that it may be interesting to evaluate if larger networks can increase sEMG classification accuracy too.
Highlights
Transradial amputees can be highly impaired, even if equipped with the most modern prostheses
The results show a better classification accuracy for the convolutional neural network compared to Support Vector Machines (SVM) in both experiments
It seems reasonable to think that they may improve the analysis of surface electromyography (sEMG) and contribute to bridge the gap between prosthetics market and recent scientific research results in rehabilitation robotics
Summary
Transradial amputees can be highly impaired, even if equipped with the most modern prostheses. A selection of the most advanced prosthetic hands available in the market according to their movement capabilities currently include the following ones: (1) Vincent hand Evolution 2; (2) Steeper Bebionic v3; (3) Otto Bock Michelangelo; and (4) Touch Bionics i-limb Quantum (Atzori and Müller, 2015). Some of these prostheses are characterized by very high dexterity: they allow the movement of up to five different fingers independently. In the most advanced cases, pattern recognition is used to control the prosthesis in combination with traditional methods This solution has been proposed since 2013 by Coaptengineering and it was recently introduced by Touch Bionics to control wrist rotation. It does not allow to control a large set of movements
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