An explicit approach for time-optimal trajectory planning for kinematically redundant serial robots

Alexander Reiter; Klemens Springer; Hubert Gattringer; Andreas Müller

An explicit approach for time-optimal trajectory planning for kinematically redundant serial robots

Alexander Reiter, Klemens Springer, Hubert Gattringer, Andreas Müller

Institute of Robotics

Research output: Chapter in Book/Report/Conference proceeding › Conference proceedings › peer-review

Abstract

Kinematically redundant serial robots have become industrially important due their increased workspace and their inherent capability of null space motion resulting in remarkable adaptiveness to specific tasks compared to conventional, non-redundant manipulators. Attempting to increase the cost-effectiveness of industrial processes, introducing minimum-time trajectories may yield economical advantages due to reduced motion cycle times. This contribution presents a method that uses joint space decomposition and analytic inverse kinematics as well as standard optimization techniques to obtain minimum-time B-spline joint trajectories along prescribed task space paths for kinematically redundant serial robots. It is shown that the present method was successfully applied to a planar manipulator.

Original language	English
Title of host publication	Proceedings in Applied Mathematics and Mechanics
Pages	67-68
Number of pages	2
Volume	15
Publication status	Published - Oct 2015

Fields of science

203015 Mechatronics
203022 Technical mechanics
202 Electrical Engineering, Electronics, Information Engineering
202035 Robotics
203013 Mechanical engineering

JKU Focus areas

Mechatronics and Information Processing

Cite this

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title = "An explicit approach for time-optimal trajectory planning for kinematically redundant serial robots",

abstract = "Kinematically redundant serial robots have become industrially important due their increased workspace and their inherent capability of null space motion resulting in remarkable adaptiveness to specific tasks compared to conventional, non-redundant manipulators. Attempting to increase the cost-effectiveness of industrial processes, introducing minimum-time trajectories may yield economical advantages due to reduced motion cycle times. This contribution presents a method that uses joint space decomposition and analytic inverse kinematics as well as standard optimization techniques to obtain minimum-time B-spline joint trajectories along prescribed task space paths for kinematically redundant serial robots. It is shown that the present method was successfully applied to a planar manipulator.",

author = "Alexander Reiter and Klemens Springer and Hubert Gattringer and Andreas M{\"u}ller",

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language = "English",

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AU - Reiter, Alexander

AU - Springer, Klemens

AU - Gattringer, Hubert

AU - Müller, Andreas

PY - 2015/10

Y1 - 2015/10

N2 - Kinematically redundant serial robots have become industrially important due their increased workspace and their inherent capability of null space motion resulting in remarkable adaptiveness to specific tasks compared to conventional, non-redundant manipulators. Attempting to increase the cost-effectiveness of industrial processes, introducing minimum-time trajectories may yield economical advantages due to reduced motion cycle times. This contribution presents a method that uses joint space decomposition and analytic inverse kinematics as well as standard optimization techniques to obtain minimum-time B-spline joint trajectories along prescribed task space paths for kinematically redundant serial robots. It is shown that the present method was successfully applied to a planar manipulator.

AB - Kinematically redundant serial robots have become industrially important due their increased workspace and their inherent capability of null space motion resulting in remarkable adaptiveness to specific tasks compared to conventional, non-redundant manipulators. Attempting to increase the cost-effectiveness of industrial processes, introducing minimum-time trajectories may yield economical advantages due to reduced motion cycle times. This contribution presents a method that uses joint space decomposition and analytic inverse kinematics as well as standard optimization techniques to obtain minimum-time B-spline joint trajectories along prescribed task space paths for kinematically redundant serial robots. It is shown that the present method was successfully applied to a planar manipulator.

M3 - Conference proceedings

VL - 15

SP - 67

EP - 68

BT - Proceedings in Applied Mathematics and Mechanics

ER -