Design Human-Robot Collaborative Lifting Task Using Optimization

Volume 2: 41st Computers and Information in Engineering Conference (CIE) Pub Date : 2021-08-17 DOI:10.1115/detc2021-71818

Asif Arefeen, Y. Xiang

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引用次数: 4

Abstract

In this paper, an optimization-based dynamic modeling method is used for human-robot lifting motion prediction. The three-dimensional (3D) human arm model has 13 degrees of freedom (DOFs) and the 3D robotic arm (Sawyer robotic arm) has 10 DOFs. The human arm and robotic arm are built in Denavit-Hartenberg (DH) representation. In addition, the 3D box is modeled as a floating-base rigid body with 6 global DOFs. The interactions between human arm and box, and robot and box are modeled as a set of grasping forces which are treated as unknowns (design variables) in the optimization formulation. The inverse dynamic optimization is used to simulate the lifting motion where the summation of joint torque squares of human arm is minimized subjected to physical and task constraints. The design variables are control points of cubic B-splines of joint angle profiles of the human arm, robotic arm, and box, and the box grasping forces at each time point. A numerical example is simulated for huma-robot lifting with a 10 Kg box. The human and robotic arms’ joint angle, joint torque, and grasping force profiles are reported. These optimal outputs can be used as references to control the human-robot collaborative lifting task.

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人机协同起重任务优化设计

本文采用基于优化的动态建模方法进行人机升降运动预测。三维(3D)人体手臂模型具有13个自由度(DOFs)，三维机械臂(Sawyer机械臂)具有10个自由度。人的手臂和机械手臂是在Denavit-Hartenberg (DH)表示。此外，将三维箱体建模为具有6个全局自由度的浮基刚体。将人的手臂与箱体、机器人与箱体之间的相互作用建模为一组抓取力，在优化公式中将其作为未知量(设计变量)处理。采用逆动力学优化方法模拟了在物理条件和任务约束下，人体手臂关节力矩平方和最小的升降运动。设计变量为人臂、机械臂和箱体关节角轮廓的三次b样条控制点以及各时间点的箱体抓握力。以人-机器人搬运一个10 Kg的箱子为例进行了数值模拟。报道了人臂和机械臂的关节角、关节力矩和抓握力分布。这些最优输出可作为控制人机协同起重任务的参考。

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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Volume 2: 41st Computers and Information in Engineering Conference (CIE)

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