Title :
Variable Joint-Velocity Limits of Redundant Robot Manipulators Handled by Quadratic Programming
Author :
Zhijun Zhang ; Yunong Zhang
Author_Institution :
Sch. of Inf. Sci. & Technol., Sun Yat-Sen Univ., Guangzhou, China
Abstract :
In this paper, a variable joint-velocity limits (VJVL)-constrained minimum-velocity-norm (MVN) scheme (termed VJVL-constrained MVN scheme) is proposed and investigated for redundant manipulators, i.e., the JVL change with the end-effector and joints movement. The scheme is then formulated as a quadratic program (QP), which is subject to an equality constraint and a bound constraint, and such a QP problem is solved by a discrete QP solver, i.e., a numerical algorithm. In addition, experimental results performed on a planar six degrees-of-freedom (6-DOF) push-rod (PR) redundant robot manipulator substantiate the physical realizability and efficacy of such a VJVL-constrained MVN scheme and the corresponding discrete QP solver. Furthermore, the position-error analyses verify the accuracy of the proposed scheme on redundant manipulators.
Keywords :
manipulator dynamics; position control; quadratic programming; redundant manipulators; PR; VJVL-constrained MVN; discrete QP solver; minimum-velocity-norm scheme; numerical algorithm; planar degrees-of-freedom push-rod redundant robot manipulator; position-error analyses; quadratic programming; variable joint-velocity limits; Artificial neural networks; Hardware; Joints; Manipulators; Redundancy; Vectors; Numerical quadratic-program (QP) solver; physical experimental verification; push-rod (PR) robot manipulator; resolving redundancy; variable joint-velocity limits (VJVL);
Journal_Title :
Mechatronics, IEEE/ASME Transactions on
DOI :
10.1109/TMECH.2011.2181977
