Impedance-Based Feedforward Learning Control for Natural Interaction between a Prosthetic Hand and the Environment

Alex Gibbs; Tomias Scott; Cesar Gonzalez; Renan Barbosa; Ronald Coro; Robert Dizor; Stephen Mccrory; Bradley Regez; S. M. Mizanoor Rahman

doi:10.1109/ICHMS53169.2021.9582650

Impedance-Based Feedforward Learning Control for Natural Interaction between a Prosthetic Hand and the Environment

Alex Gibbs, Tomias Scott, Cesar Gonzalez, Renan Barbosa, Ronald Coro, Robert Dizor, Stephen Mccrory, Bradley Regez, S. M. Mizanoor Rahman

Penn State Scranton

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

1 Scopus citations

Abstract

Robotic prosthetic hands or arms often do not apply appropriate force and pressure and also do not have appropriate tactile and proprioceptive feedbacks as accurately and precisely as a human, which make the prosthetic arms less user-friendly and inconvenient. The lack of human-like tactile and proprioceptive feedbacks may also cause serious safety problems in the interaction between a prosthetic arm and the environment. This paper proposes a supervised learning-based solution to this problem associated with a support vector machine (SVM) classifier, which is to create a method that allows the synthetic hand or a prosthetic arm to apply forces to the environment (and react to the forces applied by the environment on the prosthetic arm in the form of tactile and proprioceptive forces or pressures) properly. As part of the entire goal, we create a glove instrumented with piezoelectric tactile sensors that fits over one of the hands, applies forces on the environment (an object grasped by a human subject wearing the glove) and records the applied forces/pressures along with proprioceptive and tactile feedbacks. In a simple user study, we subjectively evaluate the interaction between the environment and the human hand wearing the glove. Based on the user study results and the measured forces, we then outline a supervised learning algorithm to be applied with a support vector machine to classify the natural and unnatural interactions between the glove (potential prosthetic arm) and the object (environment). The learned (trained) algorithm is then proposed to be used to develop feedforward learning control for achieving human-like natural interactions between the prosthetic arm and the environment.

Original language	English (US)
Title of host publication	Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021
Editors	Andreas Nurnberger, Giancarlo Fortino, Antonio Guerrieri, David Kaber, David Mendonca, Malte Schilling, Zhiwen Yu
Publisher	Institute of Electrical and Electronics Engineers Inc.
ISBN (Electronic)	9781665401708
DOIs	https://doi.org/10.1109/ICHMS53169.2021.9582650
State	Published - Sep 8 2021
Event	2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021 - Magdeburg, Germany Duration: Sep 8 2021 → Sep 10 2021

Publication series

Name	Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021

Conference

Conference	2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021
Country/Territory	Germany
City	Magdeburg
Period	9/8/21 → 9/10/21

All Science Journal Classification (ASJC) codes

Artificial Intelligence
Computer Science Applications
Human-Computer Interaction
Media Technology
Control and Optimization

Access to Document

10.1109/ICHMS53169.2021.9582650

Cite this

Gibbs, A., Scott, T., Gonzalez, C., Barbosa, R., Coro, R., Dizor, R., Mccrory, S., Regez, B., & Mizanoor Rahman, S. M. (2021). Impedance-Based Feedforward Learning Control for Natural Interaction between a Prosthetic Hand and the Environment. In A. Nurnberger, G. Fortino, A. Guerrieri, D. Kaber, D. Mendonca, M. Schilling, & Z. Yu (Eds.), Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021 (Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/ICHMS53169.2021.9582650

Gibbs, Alex ; Scott, Tomias ; Gonzalez, Cesar et al. / Impedance-Based Feedforward Learning Control for Natural Interaction between a Prosthetic Hand and the Environment. Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021. editor / Andreas Nurnberger ; Giancarlo Fortino ; Antonio Guerrieri ; David Kaber ; David Mendonca ; Malte Schilling ; Zhiwen Yu. Institute of Electrical and Electronics Engineers Inc., 2021. (Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021).

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title = "Impedance-Based Feedforward Learning Control for Natural Interaction between a Prosthetic Hand and the Environment",

abstract = "Robotic prosthetic hands or arms often do not apply appropriate force and pressure and also do not have appropriate tactile and proprioceptive feedbacks as accurately and precisely as a human, which make the prosthetic arms less user-friendly and inconvenient. The lack of human-like tactile and proprioceptive feedbacks may also cause serious safety problems in the interaction between a prosthetic arm and the environment. This paper proposes a supervised learning-based solution to this problem associated with a support vector machine (SVM) classifier, which is to create a method that allows the synthetic hand or a prosthetic arm to apply forces to the environment (and react to the forces applied by the environment on the prosthetic arm in the form of tactile and proprioceptive forces or pressures) properly. As part of the entire goal, we create a glove instrumented with piezoelectric tactile sensors that fits over one of the hands, applies forces on the environment (an object grasped by a human subject wearing the glove) and records the applied forces/pressures along with proprioceptive and tactile feedbacks. In a simple user study, we subjectively evaluate the interaction between the environment and the human hand wearing the glove. Based on the user study results and the measured forces, we then outline a supervised learning algorithm to be applied with a support vector machine to classify the natural and unnatural interactions between the glove (potential prosthetic arm) and the object (environment). The learned (trained) algorithm is then proposed to be used to develop feedforward learning control for achieving human-like natural interactions between the prosthetic arm and the environment.",

author = "Alex Gibbs and Tomias Scott and Cesar Gonzalez and Renan Barbosa and Ronald Coro and Robert Dizor and Stephen Mccrory and Bradley Regez and {Mizanoor Rahman}, {S. M.}",

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language = "English (US)",

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editor = "Andreas Nurnberger and Giancarlo Fortino and Antonio Guerrieri and David Kaber and David Mendonca and Malte Schilling and Zhiwen Yu",

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Gibbs, A, Scott, T, Gonzalez, C, Barbosa, R, Coro, R, Dizor, R, Mccrory, S, Regez, B & Mizanoor Rahman, SM 2021, Impedance-Based Feedforward Learning Control for Natural Interaction between a Prosthetic Hand and the Environment. in A Nurnberger, G Fortino, A Guerrieri, D Kaber, D Mendonca, M Schilling & Z Yu (eds), Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021. Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021, Institute of Electrical and Electronics Engineers Inc., 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021, Magdeburg, Germany, 9/8/21. https://doi.org/10.1109/ICHMS53169.2021.9582650

Impedance-Based Feedforward Learning Control for Natural Interaction between a Prosthetic Hand and the Environment. / Gibbs, Alex; Scott, Tomias; Gonzalez, Cesar et al.
Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021. ed. / Andreas Nurnberger; Giancarlo Fortino; Antonio Guerrieri; David Kaber; David Mendonca; Malte Schilling; Zhiwen Yu. Institute of Electrical and Electronics Engineers Inc., 2021. (Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

TY - GEN

T1 - Impedance-Based Feedforward Learning Control for Natural Interaction between a Prosthetic Hand and the Environment

AU - Gibbs, Alex

AU - Scott, Tomias

AU - Gonzalez, Cesar

AU - Barbosa, Renan

AU - Coro, Ronald

AU - Dizor, Robert

AU - Mccrory, Stephen

AU - Regez, Bradley

AU - Mizanoor Rahman, S. M.

PY - 2021/9/8

Y1 - 2021/9/8

N2 - Robotic prosthetic hands or arms often do not apply appropriate force and pressure and also do not have appropriate tactile and proprioceptive feedbacks as accurately and precisely as a human, which make the prosthetic arms less user-friendly and inconvenient. The lack of human-like tactile and proprioceptive feedbacks may also cause serious safety problems in the interaction between a prosthetic arm and the environment. This paper proposes a supervised learning-based solution to this problem associated with a support vector machine (SVM) classifier, which is to create a method that allows the synthetic hand or a prosthetic arm to apply forces to the environment (and react to the forces applied by the environment on the prosthetic arm in the form of tactile and proprioceptive forces or pressures) properly. As part of the entire goal, we create a glove instrumented with piezoelectric tactile sensors that fits over one of the hands, applies forces on the environment (an object grasped by a human subject wearing the glove) and records the applied forces/pressures along with proprioceptive and tactile feedbacks. In a simple user study, we subjectively evaluate the interaction between the environment and the human hand wearing the glove. Based on the user study results and the measured forces, we then outline a supervised learning algorithm to be applied with a support vector machine to classify the natural and unnatural interactions between the glove (potential prosthetic arm) and the object (environment). The learned (trained) algorithm is then proposed to be used to develop feedforward learning control for achieving human-like natural interactions between the prosthetic arm and the environment.

AB - Robotic prosthetic hands or arms often do not apply appropriate force and pressure and also do not have appropriate tactile and proprioceptive feedbacks as accurately and precisely as a human, which make the prosthetic arms less user-friendly and inconvenient. The lack of human-like tactile and proprioceptive feedbacks may also cause serious safety problems in the interaction between a prosthetic arm and the environment. This paper proposes a supervised learning-based solution to this problem associated with a support vector machine (SVM) classifier, which is to create a method that allows the synthetic hand or a prosthetic arm to apply forces to the environment (and react to the forces applied by the environment on the prosthetic arm in the form of tactile and proprioceptive forces or pressures) properly. As part of the entire goal, we create a glove instrumented with piezoelectric tactile sensors that fits over one of the hands, applies forces on the environment (an object grasped by a human subject wearing the glove) and records the applied forces/pressures along with proprioceptive and tactile feedbacks. In a simple user study, we subjectively evaluate the interaction between the environment and the human hand wearing the glove. Based on the user study results and the measured forces, we then outline a supervised learning algorithm to be applied with a support vector machine to classify the natural and unnatural interactions between the glove (potential prosthetic arm) and the object (environment). The learned (trained) algorithm is then proposed to be used to develop feedforward learning control for achieving human-like natural interactions between the prosthetic arm and the environment.

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M3 - Conference contribution

AN - SCOPUS:85118920620

T3 - Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021

BT - Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021

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A2 - Kaber, David

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A2 - Schilling, Malte

A2 - Yu, Zhiwen

PB - Institute of Electrical and Electronics Engineers Inc.

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Y2 - 8 September 2021 through 10 September 2021

ER -

Gibbs A, Scott T, Gonzalez C, Barbosa R, Coro R, Dizor R et al. Impedance-Based Feedforward Learning Control for Natural Interaction between a Prosthetic Hand and the Environment. In Nurnberger A, Fortino G, Guerrieri A, Kaber D, Mendonca D, Schilling M, Yu Z, editors, Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021. Institute of Electrical and Electronics Engineers Inc. 2021. (Proceedings of the 2021 IEEE International Conference on Human-Machine Systems, ICHMS 2021). doi: 10.1109/ICHMS53169.2021.9582650

Impedance-Based Feedforward Learning Control for Natural Interaction between a Prosthetic Hand and the Environment

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