Dynamic parameter identification based on improved particle swarm optimization and comprehensive excitation trajectory for 6R robotic arm

Industrial Robot Pub Date : 2023-12-04 DOI:10.1108/ir-07-2023-0157

Feifei Zhong, Guoping Liu, Zhenyu Lu, Lingyan Hu, Yangyang Han, Yusong Xiao, Xinrui Zhang

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引用次数: 0

Abstract

Purpose

Robotic arms’ interactions with the external environment are growing more intricate, demanding higher control precision. This study aims to enhance control precision by establishing a dynamic model through the identification of the dynamic parameters of a self-designed robotic arm.

Design/methodology/approach

This study proposes an improved particle swarm optimization (IPSO) method for parameter identification, which comprehensively improves particle initialization diversity, dynamic adjustment of inertia weight, dynamic adjustment of local and global learning factors and global search capabilities. To reduce the number of particles and improve identification accuracy, a step-by-step dynamic parameter identification method was also proposed. Simultaneously, to fully unleash the dynamic characteristics of a robotic arm, and satisfy boundary conditions, a combination of high-order differentiable natural exponential functions and traditional Fourier series is used to develop an excitation trajectory. Finally, an arbitrary verification trajectory was planned using the IPSO to verify the accuracy of the dynamical parameter identification.

Findings

Experiments conducted on a self-designed robotic arm validate the proposed parameter identification method. By comparing it with IPSO1, IPSO2, IPSOd and least-square algorithms using the criteria of torque error and root mean square for each joint, the superiority of the IPSO algorithm in parameter identification becomes evident. In this case, the dynamic parameter results of each link are significantly improved.

Originality/value

A new parameter identification model was proposed and validated. Based on the experimental results, the stability of the identification results was improved, providing more accurate parameter identification for further applications.

查看原文本刊更多论文

基于改进粒子群优化和综合激励轨迹的6R机械臂动态参数辨识

机器人手臂与外界环境的相互作用越来越复杂，对控制精度的要求也越来越高。本研究通过对自主设计机械臂的动力学参数进行辨识，建立动力学模型，提高控制精度。本研究提出了一种改进的粒子群优化(IPSO)参数辨识方法，该方法综合提高了粒子初始化多样性、惯性权值动态调整、局部和全局学习因子动态调整以及全局搜索能力。为了减少颗粒数量，提高识别精度，提出了一种分步动态参数识别方法。同时，为了充分释放机械臂的动力学特性，并满足边界条件，采用高阶可微自然指数函数与传统傅立叶级数相结合的方法建立了激励轨迹。最后，利用IPSO规划了任意验证轨迹，验证了动态参数辨识的准确性。在自行设计的机械臂上进行的实验验证了所提出的参数识别方法。将IPSO算法与IPSO1、IPSO2、IPSOd和最小二乘算法进行比较，并以各关节的扭矩误差和均方根为准则，证明了IPSO算法在参数辨识方面的优越性。在这种情况下，各环节的动态参数结果明显改善。提出并验证了一种新的参数辨识模型。在实验结果的基础上，提高了识别结果的稳定性，为进一步的应用提供了更准确的参数识别。

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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来源期刊

Industrial Robot

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