Method of Multi-objective Trajectory Planning of Parallel Mechanism Based on the Kinematics

被引：4

作者：

Chen D. ^{[1
]}

Li S. ^{[1
]}

Wang J. ^{[1
]}

He W. ^{[1
]}

Feng Y. ^{[1
]}

机构：

[1] School of Mechanical Science & Engineering, Huazhong University of Science & Technology, Wuhan

来源：

Jixie Gongcheng Xuebao/Journal of Mechanical Engineering | 2019年 / 55卷 / 15期

关键词：

B-spline curve; Multi-objective optimization; Parallel mechanism; Trajectory planning;

D O I：

10.3901/JME.2019.15.163

中图分类号：

学科分类号：

摘要：

A singular-free trajectory planning method based on the kinematics is proposed to meet the various requirements of the assembly task. On the basis of kinematic analysis of parallel mechanism, a sufficient and necessary condition is proved for realizing the singular-free trajectory planning of parallel mechanism under certain pose conditions. Then a five-order B-spline curve is employed to parameterize the trajectory of the end-effector of the parallel mechanism. Three kinematic indexes related to the assembly task, that is, the total adjustment time, the jerk of each link and the difficulty of aligning the pose of the end-effector, are selected and defined as three objective functions to evaluate the performance of the trajectory. In a simulation case, the artificial immune algorithm is used to optimize the multi-objective optimization model of the parameterized trajectory and thirty-six B-spline parameters of the trajectory are obtained. Finally, the optimal trajectory of the parallel mechanism and each link satisfying the requirement of assembly task are obtained by means of average optimal evaluation method. © 2019 Automation of Electric Power Systems Press.

引用

页码：163 / 173

页数：10

共 20 条

[1] Liu X.R., The accuracy analysis of parallel mechanism assembly robot, Applied Mechanics & Materials, 423-426, pp. 2769-2775, (2013)
[2] Zou J., Zhou W., Han X., Normal adjusting algorithm of a 3-RPS parallel mechanism in airplane assembly, China Mechanical Engineering, 5, pp. 557-560, (2011)
[3] Zhang B., Fang Q., Ke Y., Optimal time trajectory planning method for a kind of posture aligning system of large rigid bodies, Chinese Journal of Mechanical Engineering, 44, 8, pp. 248-252, (2008)
[4] Zhu Y., Huang X., Song L., Et al., Polynomial trajectory planning method based on ideal drive forces for aircraft fuselage pose adjustment, Computer Integrated Manufacturing Systems, 21, 7, pp. 1790-1796, (2015)
[5] Li X., Hu L., Wang H., PSO-based time optimal trajectory planning for six degrees of freedom robot manipulators with speed constraints, CAAI Transactions on Intelligent Systems, 3, pp. 393-398, (2015)
[6] Mei J., Zang J., Qiao Z., Et al., Trajectory planning of 3-DOF delta parallel manipulator, Journal of Mechanical Engineering, 52, 19, pp. 9-17, (2016)
[7] Chen C.T., Pham H.V., Trajectory planning in parallel kinematic manipulators using a constrained multi-objective evolutionary algorithm, Nonlinear Dynamics, 67, 2, pp. 1669-1681, (2011)
[8] Chen C.T., Liao T.T., A hybrid strategy for the time- and energy-efficient trajectory planning of parallel platform manipulators, Robotics and Computer-Integrated Manufacturing, 27, 1, pp. 72-81, (2011)
[9] Jahanpour J., Motallebi M., Porghoveh M., A novel trajectory planning scheme for parallel machining robots enhanced with NURBS curves, Journal of Intelligent & Robotic Systems, 82, 2, pp. 257-275, (2016)
[10] Wang S.A., Wu S., Kang C., Et al., Trajectory planning of a parallel manipulator based on kinematic transmission property, Intelligent Service Robotics, 8, 3, pp. 129-139, (2015)

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