Synthesis of flatness control for a multi-axis robot manipulator: An experimental approach

2011 IEEE International Symposium on Robotic and Sensors Environments (ROSE) Pub Date : 2011-10-24 DOI:10.1109/ROSE.2011.6058539

M. Allouache, M. Lowenberg, D. Wagg

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引用次数: 3

Abstract

This paper reports the results of research conducted on designing, modelling and controlling an electro-mechanical robot manipulator that serves as a sensing and motion system for hybrid testing. The conceptual design was inspired by the Stewart Platform mechanism for a two-degree-of-freedom (2DoF) moving platform. This design resulted in non-linear kinematics, coupled dynamics and an inertial moving platform that attracted model-based control strategies. A novel control technique based on differential geometric flatness was successfully implemented on this manipulator to simultaneously achieve linearisation, decoupling and asymptotic tracking. Simulation results demonstrated the validity of the proposed approach that established a robust control formulation resulting in perfect trajectory tracking at different excitation conditions. For the experimental implementation, the actuator time-delays was compensated for using forward prediction algorithms based on a fourth-order polynomial extrapolation. This compensation demonstrated a well synchronised control signal at varying frequencies.

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多轴机械臂平面度综合控制的实验方法

本文报道了一种用于混合测试的传感和运动系统的机电机器人机械手的设计、建模和控制的研究结果。概念设计的灵感来自于Stewart平台机构的两自由度(2DoF)移动平台。这种设计产生了非线性运动学、耦合动力学和惯性运动平台，吸引了基于模型的控制策略。采用基于微分几何平面度的控制方法，实现了机器人的线性化、解耦和渐近跟踪。仿真结果验证了该方法的有效性，建立了鲁棒控制公式，在不同激励条件下均能实现完美的轨迹跟踪。在实验实现中，采用基于四阶多项式外推的前向预测算法补偿执行器时延。这种补偿证明了在不同频率下控制信号的良好同步。

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

2011 IEEE International Symposium on Robotic and Sensors Environments (ROSE)

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