Modeling and adaptive control of redundant robots

Flexibility and versatility are two basic requirements for industrial robots used in manufacturing areas. In the present paper, a kinematic transformation for redundant robots between Cartesian and joint coordinates is achieved in the trajectory planner. This problem is treated by taking into accoun

Flexible and dexterous manipulation of modem industrial applications requires the use of robots with extra (more than six) axes of motion (degrees of freedom). Thus the kinematic and control considerations of redundant robots are currently of increasing interest to both theorists and practitioners.

An economical adaptive controller is presented for flexible joint robots with arbitrary joint stiffness. It does not necessarily require the time derivatives of the regressor matrix while still providing stable closed-loop tracking performance.

This paper presents a composite control approach to the adaptive control of flexible joint robots. The scheme requires augmented measurements of torque by using strain gauges mounted on the joint transmission shafts. Simulation results for a three-degree-of-freedom direct drive flexible joint arm c