Model-based adaptive hybrid control for geometrically constrained robots

Author

Arimoto, Suguru ; Liu, Yun Hui ; Naniwa, Tomohide

Author_Institution

Fac. of Eng., Tokyo Univ., Japan

fYear

1993

fDate

2-6 May 1993

Firstpage

618

Abstract

A model-based adaptive controller for robot manipulators under geometric endpoint constraint is proposed. It is based on joint-space orthogonalization of feedback signals. The adaptive law is devised by referring to the basic properties of robot dynamics, which are passivity of robot dynamics, use of feedback of residual error velocity and position signals that are projected to the tangent plane in joint space and orthogonal to the joint force vector caused by the contact, and use of the fact that important but uncertain physical parameters enter linearly in the equation of motion of robots. The convergence of tracking errors on the surface is proved under an appropriate initial condition and the smoothness of the surface. The convergence of force error is proved provided that the endpoint is kept in contact with the surface

Keywords

model reference adaptive control systems; robots; MRAC; dynamics passivity; feedback; feedback signals; force error convergence; geometric endpoint constraint; geometrically constrained robots; joint-space orthogonalization; model-based adaptive hybrid control; position; residual error velocity; robot manipulators; tracking error convergence; Adaptive control; Convergence; Equations; Estimation error; Force feedback; Lagrangian functions; Orbital robotics; Programmable control; Robots; Solid modeling;

fLanguage

English

Publisher

ieee

Conference_Titel

Robotics and Automation, 1993. Proceedings., 1993 IEEE International Conference on

Conference_Location

Atlanta, GA

Print_ISBN

0-8186-3450-2

Type

conf

DOI

10.1109/ROBOT.1993.292047

Filename

292047