Optimal design of robot accuracy compensators

Proceedings, 1989 International Conference on Robotics and Automation Pub Date : 1989-05-14 DOI:10.1109/ROBOT.1989.100074

H. Zhuang, Z. Roth, F. Hamano

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引用次数: 11

Abstract

The design of a kinematic accuracy compensator for a robot manipulator by using linear optimal control theory is discussed. The method is based on the assumption that either the actual kinematic parameters of the robot have been previously identified or that the pose errors of the manipulator can be measured online. A general mathematical framework is used, so that any linearized error model derived from the corresponding kinematic model can be used to construct an effective robot accuracy compensator. The additive corrections of joint commands are found by a linear quadratic regulator algorithm without explicitly solving the inverse kinematic problem for the actual robot. The weighting matrix and coefficients in the cost function can be chosen systematically to achieve specific objectives. It the poses of the manipulator can be measured online, a parameter identification phase of the robot calibration process can be eliminated, thus avoiding the need to identify all the error sources. A simplified algorithm is presented that accelerates significantly the process speed, making it suitable for real-time applications.<>

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机器人精度补偿器的优化设计

讨论了应用线性最优控制理论设计机器人机械臂运动精度补偿器的方法。该方法假设机器人的实际运动学参数已经预先确定，或者可以在线测量机械手的位姿误差。采用了一个通用的数学框架，使得从相应的运动学模型推导出的任何线性化误差模型都可以用来构造有效的机器人精度补偿器。在不明确求解实际机器人的运动学逆问题的情况下，采用线性二次调节算法求解联合指令的加性修正。可以系统地选择成本函数中的权重矩阵和系数来实现特定的目标。如果可以在线测量机械手的位姿，则可以省去机器人标定过程中的参数识别阶段，从而避免了识别所有误差源的需要。提出了一种简化算法，大大提高了处理速度，适合于实时应用。

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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Proceedings, 1989 International Conference on Robotics and Automation

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