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Actual Shape-Based Obstacle Avoidance Synthesized by Velocity–Acceleration Minimization for Redundant Manipulators: An Optimization Perspective

Boyu Ma, Zongwu Xie, Bowen Zhan, Zainan Jiang, Yang Liu, Hong Liu

2023IEEE Transactions on Systems Man and Cybernetics Systems41 citationsDOI

Abstract

From the optimization perspective, this article proposes a novel actual shape-based obstacle avoidance synthesized by velocity–acceleration minimization (ASOA-VAM) scheme that performs operational tasks safely in a complex environment utilizing redundant manipulators. Concretely, an actual shape-based obstacle avoidance (ASOA) strategy with a variable magnitude escape acceleration using the Gilbert–Johnson–Keerthi distance algorithm is presented. Trajectory tracking, the end-effector’s errors feedback, and the joint multilevel physical limits (joint angle, -velocity, and -acceleration limits) avoidance are also incorporated into this optimization scheme. Meanwhile, the velocity–acceleration minimization (VAM) measure is developed. Combining the ASOA strategy with the VAM measure, the ASOA-VAM scheme is formed and further reformulated as a quadratic program (QP). Moreover, a recurrent neural network with theoretically provable convergence is designed to solve the QP online. Finally, simulations, comparisons, and experiments of a 7-degree-of-freedom manipulator with engineering applications illustrate the ASOA-VAM scheme’s effectiveness, accuracy, superiority, and physical realizability.

Topics & Concepts

AccelerationControl theory (sociology)Obstacle avoidanceComputer scienceTrajectoryMinificationMathematicsMathematical optimizationArtificial intelligenceRobotMobile robotAstronomyControl (management)PhysicsClassical mechanicsRobotic Path Planning AlgorithmsRobotic Mechanisms and DynamicsRobot Manipulation and Learning
Actual Shape-Based Obstacle Avoidance Synthesized by Velocity–Acceleration Minimization for Redundant Manipulators: An Optimization Perspective | Litcius