Abstract
Myoelectric hand prostheses offer a way for upper-limb amputees to recover gesture and prehensile abilities to ease rehabilitation and daily life activities. However, studies with prosthesis users found that a lack of intuitiveness and ease-of-use in the human-machine control interface are among the main driving factors in the low user acceptance of these devices. This paper proposes a highly intuitive, responsive and reliable real-time myoelectric hand prosthesis control strategy with an emphasis on the demonstration and report of real-time evaluation metrics. The presented solution leverages surface high-density electromyography (HD-EMG) and a convolutional neural network (CNN) to adapt itself to each unique user and his/her specific voluntary muscle contraction patterns. Furthermore, a transfer learning approach is presented to drastically reduce the training time and allow for easy installation and calibration processes. The CNN-based gesture recognition system was evaluated in real-time with a group of 12 able-bodied users. A real-time test for 6 classes/grip modes resulted in mean and median positive predictive values (PPV) of 93.43% and 100%, respectively. Each gesture state is instantly accessible from any other state, with no mode switching required for increased responsiveness and natural seamless control. The system is able to output a correct prediction within less than 116 ms latency. 100% PPV has been attained in many trials and is realistically achievable consistently with user practice and/or employing a thresholded majority vote inference. Using transfer learning, these results are achievable after a sensor installation, data recording and network training/fine-tuning routine taking less than 10 min to complete, a reduction of 89.4% in the setup time of the traditional, non-transfer learning approach.
Highlights
Myoelectric hand prostheses offer a way for upper-limb amputees to recover gesture and prehensile abilities to ease rehabilitation and daily life activities
While the study was more conclusive with regression, instead of classification, the results show that users can adapt and regulate their muscle contractions successfully in reaction to error-inducing non-stationarities in the EMG signals
Leveraging transfer learning to facilitate inter-session algorithm training, the setup time for real-time operation is reduced by 89.4% on subsequent sessions
Summary
Myoelectric hand prostheses offer a way for upper-limb amputees to recover gesture and prehensile abilities to ease rehabilitation and daily life activities. High-density electromyography (HD-EMG) allows to extract patterns in the spatial distribution of motor unit action potentials (MUAP) for different gesture-specific muscle c ontractions[13,14,15,16] This method uses an array of electrodes placed over the forearm, reducing the installation process to a single sensor device instead of individual electrodes. Using processing algorithms such as a convolutional neural network (CNN) alleviates sensor placement reliance, thanks to the CNN’s property of translational invariance[17] This is in addition to the CNN’s ability of automatic feature extraction, which allows for an intuitive control interface, as intended gesture commands are decoded directly from the user’s natural muscle contraction patterns. The custom sensor fits in the socket format of common commercial myoelectric prostheses, ensuring straightforward device installation without added complexity related to HD-EMG sensing
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