Nonlinear Tracking Control Of An Antagonistic Muscle Pair Actuated System

Holly Warner; Hanz Richter; Antonie van den Bogert

Nonlinear Tracking Control Of An Antagonistic Muscle Pair Actuated System

Holly Warner, Hanz Richter, Antonie van den Bogert

Cleveland State University

Research output: Contribution to journal › Article › peer-review

Abstract

When developing a machine intended for interaction with humans such as rehabilitation equipment or powered prostheses, it is useful to test in simulation prior to hardware implementation, avoiding safety hazards. Few models of the human for such purposes are seen in the literature. This paper moves toward the realization of such a model by developing a simple muscle actuated system and related controller. The backstepping control methodology is implemented such that the controller accounts for all of the levels of intricacy presented by the Hill muscle model as an actuator, including the activation dynamics. The neural inputs are used as the actual controls. To be able to derive the control law, a modified strict-feedback form of the model is also developed. Stable tracking performance is then achieved in simulation.

Original language	American English
Journal	Proceedings Of The ASME 10th Annual Dynamic Systems And Control Conference, 2017, Vol 1
State	Published - Jan 1 2017

Disciplines

Mechanical Engineering

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http://proceedings.asmedigitalcollection.asme.org/proceeding.aspx?articleid=2663485

Cite this

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title = "Nonlinear Tracking Control Of An Antagonistic Muscle Pair Actuated System",

abstract = " When developing a machine intended for interaction with humans such as rehabilitation equipment or powered prostheses, it is useful to test in simulation prior to hardware implementation, avoiding safety hazards. Few models of the human for such purposes are seen in the literature. This paper moves toward the realization of such a model by developing a simple muscle actuated system and related controller. The backstepping control methodology is implemented such that the controller accounts for all of the levels of intricacy presented by the Hill muscle model as an actuator, including the activation dynamics. The neural inputs are used as the actual controls. To be able to derive the control law, a modified strict-feedback form of the model is also developed. Stable tracking performance is then achieved in simulation.",

author = "Holly Warner and Hanz Richter and \{van den Bogert\}, Antonie",

year = "2017",

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day = "1",

language = "American English",

journal = "Proceedings Of The ASME 10th Annual Dynamic Systems And Control Conference, 2017, Vol 1",

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AU - Warner, Holly

AU - Richter, Hanz

AU - van den Bogert, Antonie

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N2 - When developing a machine intended for interaction with humans such as rehabilitation equipment or powered prostheses, it is useful to test in simulation prior to hardware implementation, avoiding safety hazards. Few models of the human for such purposes are seen in the literature. This paper moves toward the realization of such a model by developing a simple muscle actuated system and related controller. The backstepping control methodology is implemented such that the controller accounts for all of the levels of intricacy presented by the Hill muscle model as an actuator, including the activation dynamics. The neural inputs are used as the actual controls. To be able to derive the control law, a modified strict-feedback form of the model is also developed. Stable tracking performance is then achieved in simulation.

AB - When developing a machine intended for interaction with humans such as rehabilitation equipment or powered prostheses, it is useful to test in simulation prior to hardware implementation, avoiding safety hazards. Few models of the human for such purposes are seen in the literature. This paper moves toward the realization of such a model by developing a simple muscle actuated system and related controller. The backstepping control methodology is implemented such that the controller accounts for all of the levels of intricacy presented by the Hill muscle model as an actuator, including the activation dynamics. The neural inputs are used as the actual controls. To be able to derive the control law, a modified strict-feedback form of the model is also developed. Stable tracking performance is then achieved in simulation.

UR - https://engagedscholarship.csuohio.edu/enme_facpub/354

UR - http://proceedings.asmedigitalcollection.asme.org/proceeding.aspx?articleid=2663485

M3 - Article

JO - Proceedings Of The ASME 10th Annual Dynamic Systems And Control Conference, 2017, Vol 1

JF - Proceedings Of The ASME 10th Annual Dynamic Systems And Control Conference, 2017, Vol 1

ER -

Nonlinear Tracking Control Of An Antagonistic Muscle Pair Actuated System

Abstract

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