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Hauptverfasser: Betthauser, Joseph L., Greene, Rebecca, Dhawan, Ananya, Krall, John T., Hunt, Christopher L., Levay, Gyorgy, Kaliki, Rahul R., Fifer, Matthew S., Sikdar, Siddhartha, Thakor, Nitish V.
Format: Preprint
Veröffentlicht: 2024
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Online-Zugang:https://arxiv.org/abs/2412.17991
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author Betthauser, Joseph L.
Greene, Rebecca
Dhawan, Ananya
Krall, John T.
Hunt, Christopher L.
Levay, Gyorgy
Kaliki, Rahul R.
Fifer, Matthew S.
Sikdar, Siddhartha
Thakor, Nitish V.
author_facet Betthauser, Joseph L.
Greene, Rebecca
Dhawan, Ananya
Krall, John T.
Hunt, Christopher L.
Levay, Gyorgy
Kaliki, Rahul R.
Fifer, Matthew S.
Sikdar, Siddhartha
Thakor, Nitish V.
contents One of the most elusive goals in myographic prosthesis control is the ability to reliably decode continuous positions simultaneously across multiple degrees-of-freedom. Goal: To demonstrate dexterous, natural, biomimetic finger and wrist control of the highly advanced robotic Modular Prosthetic Limb. Methods: We combine sequential temporal regression models and reinforcement learning using myographic signals to predict continuous simultaneous predictions of 7 finger and wrist degrees-of-freedom for 9 non-amputee human subjects in a minimally-constrained freeform training process. Results: We demonstrate highly dexterous 7 DoF position-based regression for prosthesis control from EMG signals, with significantly lower error rates than traditional approaches (p < 0.001) and nearly zero prediction response time delay (p < 0.001). Their performance can be continuously improved at any time using our freeform reinforcement process. Significance: We have demonstrated the most dexterous, biomimetic, and natural prosthesis control performance ever obtained from the surface EMG signal. Our reinforcement approach allowed us to abandon standard training protocols and simply allow the subject to move in any desired way while our models adapt. Conclusions: This work redefines the state-of-the-art in myographic decoding in terms of the reliability, responsiveness, and movement complexity available from prosthesis control systems. The present-day emergence and convergence of advanced algorithmic methods, experiment protocols, dexterous robotic prostheses, and sensor modalities represents a unique opportunity to finally realize our ultimate goal of achieving fully restorative natural upper-limb function for amputees.
format Preprint
id arxiv_https___arxiv_org_abs_2412_17991
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Online Adaptation for Myographic Control of Natural Dexterous Hand and Finger Movements
Betthauser, Joseph L.
Greene, Rebecca
Dhawan, Ananya
Krall, John T.
Hunt, Christopher L.
Levay, Gyorgy
Kaliki, Rahul R.
Fifer, Matthew S.
Sikdar, Siddhartha
Thakor, Nitish V.
Robotics
Computer Vision and Pattern Recognition
One of the most elusive goals in myographic prosthesis control is the ability to reliably decode continuous positions simultaneously across multiple degrees-of-freedom. Goal: To demonstrate dexterous, natural, biomimetic finger and wrist control of the highly advanced robotic Modular Prosthetic Limb. Methods: We combine sequential temporal regression models and reinforcement learning using myographic signals to predict continuous simultaneous predictions of 7 finger and wrist degrees-of-freedom for 9 non-amputee human subjects in a minimally-constrained freeform training process. Results: We demonstrate highly dexterous 7 DoF position-based regression for prosthesis control from EMG signals, with significantly lower error rates than traditional approaches (p < 0.001) and nearly zero prediction response time delay (p < 0.001). Their performance can be continuously improved at any time using our freeform reinforcement process. Significance: We have demonstrated the most dexterous, biomimetic, and natural prosthesis control performance ever obtained from the surface EMG signal. Our reinforcement approach allowed us to abandon standard training protocols and simply allow the subject to move in any desired way while our models adapt. Conclusions: This work redefines the state-of-the-art in myographic decoding in terms of the reliability, responsiveness, and movement complexity available from prosthesis control systems. The present-day emergence and convergence of advanced algorithmic methods, experiment protocols, dexterous robotic prostheses, and sensor modalities represents a unique opportunity to finally realize our ultimate goal of achieving fully restorative natural upper-limb function for amputees.
title Online Adaptation for Myographic Control of Natural Dexterous Hand and Finger Movements
topic Robotics
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2412.17991