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Main Authors: Kalbasi, Mohammad, Shaeri, MohammadAli, Mendez, Vincent Alexandre, Shokur, Solaiman, Micera, Silvestro, Shoaran, Mahsa
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2405.20052
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author Kalbasi, Mohammad
Shaeri, MohammadAli
Mendez, Vincent Alexandre
Shokur, Solaiman
Micera, Silvestro
Shoaran, Mahsa
author_facet Kalbasi, Mohammad
Shaeri, MohammadAli
Mendez, Vincent Alexandre
Shokur, Solaiman
Micera, Silvestro
Shoaran, Mahsa
contents Advancements in neural engineering have enabled the development of Robotic Prosthetic Hands (RPHs) aimed at restoring hand functionality. Current commercial RPHs offer limited control through basic on/off commands. Recent progresses in machine learning enable finger movement decoding with higher degrees of freedom, yet the high computational complexity of such models limits their application in portable devices. Future RPH designs must balance portability, low power consumption, and high decoding accuracy to be practical for individuals with disabilities. To this end, we introduce a novel attractor-based neural network to realize on-chip movement decoding for next-generation portable RPHs. The proposed architecture comprises an encoder, an attention layer, an attractor network, and a refinement regressor. We tested our model on four healthy subjects and achieved a decoding accuracy of 80.3%. Our proposed model is over 120 and 50 times more compact compared to state-of-the-art LSTM and CNN models, respectively, with comparable (or superior) decoding accuracy. Therefore, it exhibits minimal hardware complexity and can be effectively integrated as a System-on-Chip.
format Preprint
id arxiv_https___arxiv_org_abs_2405_20052
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Hardware-Efficient EMG Decoding for Next-Generation Hand Prostheses
Kalbasi, Mohammad
Shaeri, MohammadAli
Mendez, Vincent Alexandre
Shokur, Solaiman
Micera, Silvestro
Shoaran, Mahsa
Signal Processing
Machine Learning
Advancements in neural engineering have enabled the development of Robotic Prosthetic Hands (RPHs) aimed at restoring hand functionality. Current commercial RPHs offer limited control through basic on/off commands. Recent progresses in machine learning enable finger movement decoding with higher degrees of freedom, yet the high computational complexity of such models limits their application in portable devices. Future RPH designs must balance portability, low power consumption, and high decoding accuracy to be practical for individuals with disabilities. To this end, we introduce a novel attractor-based neural network to realize on-chip movement decoding for next-generation portable RPHs. The proposed architecture comprises an encoder, an attention layer, an attractor network, and a refinement regressor. We tested our model on four healthy subjects and achieved a decoding accuracy of 80.3%. Our proposed model is over 120 and 50 times more compact compared to state-of-the-art LSTM and CNN models, respectively, with comparable (or superior) decoding accuracy. Therefore, it exhibits minimal hardware complexity and can be effectively integrated as a System-on-Chip.
title Hardware-Efficient EMG Decoding for Next-Generation Hand Prostheses
topic Signal Processing
Machine Learning
url https://arxiv.org/abs/2405.20052