Nonlinear robust hybrid control of robot manipulators.

Shay Ping T. Wang; C. Y. Kuo

Nonlinear robust hybrid control of robot manipulators.

Shay Ping T. Wang, C. Y. Kuo

Research output: Contribution to journal › Conference article › peer-review

Abstract

A nonlinear robust hybrid control scheme for robot motion control is proposed. The control input consists of a nonlinear and a linear part. The nonlinear input decouples a robot dynamics and obtains a set of position and force equations in the Cartesian coordinate. The linear part applies the robust servomechanism theory to suppress position or force tracking error due to uncertainties. This nonlinear robust hybrid control scheme is applied to a two-joint SCARA-type robot, and simulation results demonstrate excellent robustness properties and satisfactory hybrid control even under severe modeling errors.

Original language	English (US)
Pages (from-to)	1345-1350
Number of pages	6
Journal	Proceedings of the American Control Conference
Volume	88 pt 1-3
State	Published - Dec 1 1988
Externally published	Yes

ASJC Scopus subject areas

Electrical and Electronic Engineering

Cite this

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title = "Nonlinear robust hybrid control of robot manipulators.",

abstract = "A nonlinear robust hybrid control scheme for robot motion control is proposed. The control input consists of a nonlinear and a linear part. The nonlinear input decouples a robot dynamics and obtains a set of position and force equations in the Cartesian coordinate. The linear part applies the robust servomechanism theory to suppress position or force tracking error due to uncertainties. This nonlinear robust hybrid control scheme is applied to a two-joint SCARA-type robot, and simulation results demonstrate excellent robustness properties and satisfactory hybrid control even under severe modeling errors.",

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AU - Kuo, C. Y.

PY - 1988/12/1

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N2 - A nonlinear robust hybrid control scheme for robot motion control is proposed. The control input consists of a nonlinear and a linear part. The nonlinear input decouples a robot dynamics and obtains a set of position and force equations in the Cartesian coordinate. The linear part applies the robust servomechanism theory to suppress position or force tracking error due to uncertainties. This nonlinear robust hybrid control scheme is applied to a two-joint SCARA-type robot, and simulation results demonstrate excellent robustness properties and satisfactory hybrid control even under severe modeling errors.

AB - A nonlinear robust hybrid control scheme for robot motion control is proposed. The control input consists of a nonlinear and a linear part. The nonlinear input decouples a robot dynamics and obtains a set of position and force equations in the Cartesian coordinate. The linear part applies the robust servomechanism theory to suppress position or force tracking error due to uncertainties. This nonlinear robust hybrid control scheme is applied to a two-joint SCARA-type robot, and simulation results demonstrate excellent robustness properties and satisfactory hybrid control even under severe modeling errors.

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M3 - Conference article

AN - SCOPUS:18544396999

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JF - Proceedings of the American Control Conference

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Nonlinear robust hybrid control of robot manipulators.

Abstract

ASJC Scopus subject areas

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