Litcius/Paper detail

Adaptive Manipulability-Based Path Planning Strategy for Industrial Robot Manipulators

Henghua Shen, Wenfang Xie, Jianyu Tang, Tao Zhou

2023IEEE/ASME Transactions on Mechatronics59 citationsDOI

Abstract

In this article, a novel manipulability-based optimal rapidly exploring random tree (RRT*) path planning strategy is proposed for industrial robot manipulators. When sampling in the search space, two constraints, namely, path length and manipulability measure, are imposed to find a minimal-cost path connecting the start and goal points. By tracking the generated path, a robot manipulator's end-effector can traverse the workspace with a shorter length and, meanwhile, avoid configuration singularities. A constrained closed-loop inverse kinematics technique is utilized to exploit the kinematic redundancy to assign a higher manipulability to an end-effector position. Additionally, the metrics of path length and manipulability measure are used to determine the adaptive step size for the RRT* planner. This helps the space-filling tree to grow efficiently toward unsearched areas and find an optimal path. Simulation analysis and experimental results of a six-degree-of-freedom FANUC-M-20iA industrial robot illustrate the efficiency of the proposed path planning methods.

Topics & Concepts

Motion planningWorkspacePath (computing)Control theory (sociology)KinematicsRandom treeRobotMeasure (data warehouse)TraverseRobot end effectorIndustrial robotInverse kinematicsComputer scienceConfiguration spaceMathematical optimizationPath lengthMathematicsArtificial intelligenceControl (management)Computer networkProgramming languageClassical mechanicsDatabaseGeodesyQuantum mechanicsGeographyPhysicsRobotic Path Planning AlgorithmsRobotic Mechanisms and DynamicsRobot Manipulation and Learning