Optimal time-jerk-torque trajectory planning of industrial robot under kinematic and dynamic constraints

2019 9th Annual Information Technology, Electromechanical Engineering and Microelectronics Conference (IEMECON) Pub Date : 2019-03-01 DOI:10.1109/IEMECONX.2019.8877063

A. Rout, Golak Bihari Mohanta, B. Gunji, B. Deepak, B. Biswal

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引用次数: 2

Abstract

In this paper, an offline optimal trajectory planning of 6-axis industrial subjected to both kinematic and dynamic constraints has been presented. The positional accuracy of the robot end effector and smoothness of the robot travel can be achieved by minimizing the torque rate and joint jerks. But this results in vast increase in total travel time of robot which as a result affects the productivity. This leads to a formulation of a multi-objective optimization, as jerk and torque rate functions are contradictory to time interval function. Therefore, a new and efficient Hybrid Multi-Objective Evolutionary Algorithm (HMOEA) i.e. Non-Dominated Sorting Genetic Algorithm (NSGA-II) combined with Nelder-Mead simplex method with better local search has been proposed to obtain an optimal Pareto front consisting of non-dominated solutions that can give best trade-off between the objectives. Finally, the optimal results have been validated through simulation and experiment using Kawasaki RS06L 6-axis robot available in product development laboratory of department.

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运动学和动力学约束下工业机器人最优时间-扭矩轨迹规划

本文提出了一种同时考虑运动学和动力学约束的六轴工业脱机最优轨迹规划方法。通过最小化力矩速率和关节位移，可以实现机器人末端执行器的位置精度和机器人行走的平稳性。但这导致机器人的总行程时间大大增加，从而影响了生产率。这导致了一个多目标优化的公式，因为加速度和扭矩速率函数与时间间隔函数是矛盾的。为此，提出了一种新的高效混合多目标进化算法(HMOEA)，即非支配排序遗传算法(NSGA-II)与具有更好局部搜索性能的Nelder-Mead单纯形法相结合，以获得由非支配解组成的最优Pareto front，该Pareto front可以在目标之间实现最佳权衡。最后，利用部门产品开发实验室现有的川崎RS06L六轴机器人，通过仿真和实验验证了优化结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2019 9th Annual Information Technology, Electromechanical Engineering and Microelectronics Conference (IEMECON)

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