Application of the Actor-Critic Architecture to Functional Electrical Stimulation Control of a Human Arm

Philip Thomas; Michael Branicky; Antonie van den Bogert; Kathleen Jagodnik

Application of the Actor-Critic Architecture to Functional Electrical Stimulation Control of a Human Arm

Philip Thomas, Michael Branicky, Antonie van den Bogert, Kathleen Jagodnik

Case Western Reserve University

Research output: Other contribution

Abstract

Clinical tests have shown that the dynamics of a human arm, controlled using Functional Electrical Stimulation (FES), can vary significantly between and during trials. In this paper, we study the application of the actor-critic architecture, with neural networks for the both the actor and the critic, as a controller that can adapt to these changing dynamics of a human arm. Development and tests were done in simulation using a planar arm model and Hill-based muscle dynamics. We begin by training it using a Proportional Derivative (PD) controller as a supervisor. We then make clinically relevant changes to the dynamics of the arm and test the actor-critic’s ability to adapt without supervision in a reasonable number of episodes. Finally, we devise methods for achieving both rapid learning and long-term stability.

Original language	American English
State	Published - Jan 1 2009

Keywords

Continuous actor-critic; stability; robustness; reinforcement learning; adaptive controller; functional electrical stimulation; human arm; artificial neural network; proportional derivative controller; proportional integral derivative controller; locally weighted regression

Disciplines

Biomechanical Engineering

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Application of the Actor-Critic Architecture to Functional ElectrFinal published version, 2 MBLicense: CC BY

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title = "Application of the Actor-Critic Architecture to Functional Electrical Stimulation Control of a Human Arm",

abstract = " Clinical tests have shown that the dynamics of a human arm, controlled using Functional Electrical Stimulation (FES), can vary significantly between and during trials. In this paper, we study the application of the actor-critic architecture, with neural networks for the both the actor and the critic, as a controller that can adapt to these changing dynamics of a human arm. Development and tests were done in simulation using a planar arm model and Hill-based muscle dynamics. We begin by training it using a Proportional Derivative (PD) controller as a supervisor. We then make clinically relevant changes to the dynamics of the arm and test the actor-critic{\textquoteright}s ability to adapt without supervision in a reasonable number of episodes. Finally, we devise methods for achieving both rapid learning and long-term stability.",

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T1 - Application of the Actor-Critic Architecture to Functional Electrical Stimulation Control of a Human Arm

AU - Thomas, Philip

AU - Branicky, Michael

AU - van den Bogert, Antonie

AU - Jagodnik, Kathleen

PY - 2009/1/1

Y1 - 2009/1/1

N2 - Clinical tests have shown that the dynamics of a human arm, controlled using Functional Electrical Stimulation (FES), can vary significantly between and during trials. In this paper, we study the application of the actor-critic architecture, with neural networks for the both the actor and the critic, as a controller that can adapt to these changing dynamics of a human arm. Development and tests were done in simulation using a planar arm model and Hill-based muscle dynamics. We begin by training it using a Proportional Derivative (PD) controller as a supervisor. We then make clinically relevant changes to the dynamics of the arm and test the actor-critic’s ability to adapt without supervision in a reasonable number of episodes. Finally, we devise methods for achieving both rapid learning and long-term stability.

AB - Clinical tests have shown that the dynamics of a human arm, controlled using Functional Electrical Stimulation (FES), can vary significantly between and during trials. In this paper, we study the application of the actor-critic architecture, with neural networks for the both the actor and the critic, as a controller that can adapt to these changing dynamics of a human arm. Development and tests were done in simulation using a planar arm model and Hill-based muscle dynamics. We begin by training it using a Proportional Derivative (PD) controller as a supervisor. We then make clinically relevant changes to the dynamics of the arm and test the actor-critic’s ability to adapt without supervision in a reasonable number of episodes. Finally, we devise methods for achieving both rapid learning and long-term stability.

KW - Continuous actor-critic; stability; robustness; reinforcement learning; adaptive controller; functional electrical stimulation; human arm; artificial neural network; proportional derivative controller; proportional integral derivative controller; locally

UR - https://engagedscholarship.csuohio.edu/enme_facpub/411

M3 - Other contribution

ER -

Application of the Actor-Critic Architecture to Functional Electrical Stimulation Control of a Human Arm

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Keywords

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