Robust control of robotic manipulators with task space feedback

Abstract

A robust controller is proposed for the accurate trajectory control of a general n degree of freedom robotic manipulator, using feedback of task space coordinates, in the presence of large perturbations of the manipulator dynamic parameters. The controller is shown to consist of two separate devices: 1) a robust compensator which makes the system insensitive to parameter perturbation and causes asymptotic regulation to occur for a certain class of reference input/disturbance signals, and 2) a stabilizing compensator which stabilizes the closed-loop system. Asymptotic stability of the closed-loop system is demonstrated, using a Lyapunov approach, for large perturbations of the plant parameters. A numerical simulation of a two degree of freedom manipulator, with a large unknown payload mass is used to demonstrate the effectiveness of the controller.