论文信息 - Internal Redundancy – the Way to Improve Robot Dynamics and Control Performances

Internal Redundancy – the Way to Improve Robot Dynamics and Control Performances

The research follows the concept of variable geometry. The concept was originally introduced for general mechanical system in order to improve its dynamic behaviour [14]. Here, we apply the concept to robots. It can be shown that enhancement of robot dynamic performances is achieved. In this paper variation of geometry is considered equally as the motion in robot joints. Thus, a new set of degrees of freedom is introduced. This leads to redundancy – different internal motions are possible for the given external motion of the end-effector. However, there is an important difference from the usual notion of redundancy. Here, the additional joints do not influence the external motion and accordingly cannot improve the end-effector ability for maneuvering. For this reason the new notion is defined the internal redundancy.Although variation of geometry is treated equally with the motion in robot joints, there is still a difference in the aim of these new degrees of freedom. They should contribute to overcoming the limits of robot actuators, achieving better static compensation, etc. One might say that internal redundancy improves the robot dynamic capabilities. In this paper the mathematical formulation of kinematics and dynamics of robots with internal redundancy is carried out. A case study is presented in order to support the main idea.

[1] Miomir Vukobratovic,et al. A dynamic approach to nominal trajectory synthesis for redundant manipulators , 1984, IEEE Transactions on Systems, Man, and Cybernetics.

[2] Veljko Potkonjak,et al. Mathematical modelling of a redundant anthropomorphic arm (Part I) , 1992, Robotics Auton. Syst..

[3] Veljko Potkonjak. Thermal analysis and dynamic capabilities of DC motors in industrial robotic systems , 1989 .

[4] J. K. Hedrick. Railway Vehicle Active Suspensions , 1981 .

[5] Leonard Meirovitch,et al. CONTROL OF FLUTTER IN BRIDGES , 1987 .

[6] Veljko Potkonjak,et al. Dynamics of Manipulation Robots , 1982 .

[7] Neville Hogan,et al. High bandwidth force regulation and inertia reduction using a macro/micro manipulator system , 1988, Proceedings. 1988 IEEE International Conference on Robotics and Automation.

[8] M. Vukobratovic,et al. Applied Dynamics of Manipulation Robots , 1989 .

[9] Ph. D. Miomir Vukobratović D. Sc.,et al. Applied Dynamics and CAD of Manipulation Robots , 1985, Communications and Control Engineering Series.

[10] Yoshihiko Nakamura,et al. Advanced robotics - redundancy and optimization , 1990 .

[11] Olav Egeland,et al. Task-space tracking with redundant manipulators , 1987, IEEE Journal on Robotics and Automation.

[12] Veljko Potkonjak,et al. Systems With Variable Geometry: Concept and Prospects , 1999 .