Adaptive kinematic control of free-floating space robot system

Author

Ma, Baoli ; Huo, Wei

Author_Institution

Seventh Res. Div., Beijing Univ. of Aeronaut. & Astronaut., China

Volume

3

fYear

1996

fDate

4-8 Nov 1996

Firstpage

1565

Abstract

Free-floating space robot is different from the robot with inertially fixed base in that its Jacobian matrix is dependent not only on geometric parameters, but also on inertia parameters nonlinearly. Since the inertia parameters are usually not known accurately, large end-effector tracking error will be induced if the inaccurate Jacobian is used to calculate joint trajectory given the desired end-effector trajectory. In this paper, adaptive schemes are developed to generate joint rate and joint acceleration, trajectories, the proposed schemes are proved to be stable and ensure convergence of end-effector tracking error despite of the uncertainties of inertia parameters. Simulation of planar two-link free-floating space robot system is implemented to verify the proposed adaptive schemes

Keywords

Jacobian matrices; adaptive control; aerospace control; mobile robots; nonlinear control systems; robot kinematics; Jacobian matrix; adaptive kinematic control; end-effector tracking error; end-effector tracking error convergence; geometric parameters; inertia parameters; joint acceleration trajectories; joint rate; nonlinear dependence; planar two-link free-floating Space robot system; uncertainties; Acceleration; Adaptive control; Control systems; Convergence; Jacobian matrices; Kinematics; Orbital robotics; Programmable control; Trajectory; Uncertainty;

fLanguage

English

Publisher

ieee

Conference_Titel

Intelligent Robots and Systems '96, IROS 96, Proceedings of the 1996 IEEE/RSJ International Conference on

Conference_Location

Osaka

Print_ISBN

0-7803-3213-X

Type

conf

DOI

10.1109/IROS.1996.569021

Filename

569021