An algorithm of path planning for manipulator end-effector based on geometric mechanics

Wang Benliang; Gao Shan; Sun Hongwei; Shi Donghua

doi:10.6052/1672-6553-2017-074

An algorithm of path planning for manipulator end-effector based on geometric mechanics

Wang Benliang, Gao Shan, Sun Hongwei, Shi Donghua^*

^*Corresponding author for this work

School of Mathematics and Statistics

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

An online algorithm of real-time collision avoidance and trajectory tracking for the manipulator end-effector is proposed in the framework of geometric mechanics in this paper. First, the gyroscopic force is introduced in the motion of end-effector to generate its collision-free smooth trajectory in work space. Next, the corresponding smooth trajectories in the joint space are obtained by solving the inverse kinematics problem with the damped least square method. Finally, through the comparison with the classical RRT algorithm, the effectiveness of the proposed algorithm is illustrated by numerical simulations of a 6 DOF manipulator.

Original language	English
Pages (from-to)	391-396
Number of pages	6
Journal	Journal of Dynamics and Control
Volume	16
Issue number	5
DOIs	https://doi.org/10.6052/1672-6553-2017-074
Publication status	Published - Oct 2018

Keywords

Damped least squares method
Gyroscopic force
Manipulator
RRT
Reaction planning

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10.6052/1672-6553-2017-074

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title = "An algorithm of path planning for manipulator end-effector based on geometric mechanics",

abstract = "An online algorithm of real-time collision avoidance and trajectory tracking for the manipulator end-effector is proposed in the framework of geometric mechanics in this paper. First, the gyroscopic force is introduced in the motion of end-effector to generate its collision-free smooth trajectory in work space. Next, the corresponding smooth trajectories in the joint space are obtained by solving the inverse kinematics problem with the damped least square method. Finally, through the comparison with the classical RRT algorithm, the effectiveness of the proposed algorithm is illustrated by numerical simulations of a 6 DOF manipulator.",

keywords = "Damped least squares method, Gyroscopic force, Manipulator, RRT, Reaction planning",

author = "Wang Benliang and Gao Shan and Sun Hongwei and Shi Donghua",

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AU - Benliang, Wang

AU - Shan, Gao

AU - Hongwei, Sun

AU - Donghua, Shi

PY - 2018/10

Y1 - 2018/10

N2 - An online algorithm of real-time collision avoidance and trajectory tracking for the manipulator end-effector is proposed in the framework of geometric mechanics in this paper. First, the gyroscopic force is introduced in the motion of end-effector to generate its collision-free smooth trajectory in work space. Next, the corresponding smooth trajectories in the joint space are obtained by solving the inverse kinematics problem with the damped least square method. Finally, through the comparison with the classical RRT algorithm, the effectiveness of the proposed algorithm is illustrated by numerical simulations of a 6 DOF manipulator.

AB - An online algorithm of real-time collision avoidance and trajectory tracking for the manipulator end-effector is proposed in the framework of geometric mechanics in this paper. First, the gyroscopic force is introduced in the motion of end-effector to generate its collision-free smooth trajectory in work space. Next, the corresponding smooth trajectories in the joint space are obtained by solving the inverse kinematics problem with the damped least square method. Finally, through the comparison with the classical RRT algorithm, the effectiveness of the proposed algorithm is illustrated by numerical simulations of a 6 DOF manipulator.

KW - Damped least squares method

KW - Gyroscopic force

KW - Manipulator

KW - RRT

KW - Reaction planning

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EP - 396

JO - Journal of Dynamics and Control

JF - Journal of Dynamics and Control

IS - 5

ER -

An algorithm of path planning for manipulator end-effector based on geometric mechanics

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Keywords

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