Distributed adaptive leader-following control for multi-agent multi-degree manipulators with finite-time guarantees

52nd IEEE Conference on Decision and Control Pub Date : 2013-12-10 DOI:10.1109/CDC.2013.6760094

M. Mahyuddin, G. Herrmann, F. Lewis

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引用次数: 10

Abstract

A robust distributed adaptive leader-following control for multi-degree-of-freedom (multi-DOF) robot manipulator-type agents is proposed to guarantee finite-time convergence for leader-following tracking and parameter estimation via agent-based estimation and control algorithms. The dynamics of each manipulator agent system of n degrees including the leader agent are assumed unknown. For a specific leader-following network Laplacian, the agents' position, velocity and some switched control information can be fed back to the communication network. In contrast to the current multi-agent literature for robotic manipulators, the proposed approach does not require a priori information of the leader's joint velocity and acceleration to be available to all agents due to the use of agent-based robust adaptive control elements. Due to the multi-DOF character of each agent, matrix theoretical results related to M-matrix theory used for multi-agent systems needs to be extended to the multi-degree context in contrast to recent scalar double integrator results. A simulation example of two-degree of freedom manipulators exemplifies the effectiveness of the approach.

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有限时间保证多智能体多自由度机器人的分布式自适应领导-跟随控制

针对多自由度机械臂型智能体，提出了一种鲁棒分布式自适应leader-follow控制方法，通过基于智能体的估计和控制算法保证leader-follow跟踪和参数估计的有限时间收敛性。假设包括领导主体在内的n阶机械臂agent系统的动力学是未知的。对于特定的领导-跟随网络拉普拉斯算子，agent的位置、速度和一些交换控制信息可以反馈到通信网络中。与目前的多智能体机器人文献相比，由于使用基于智能体的鲁棒自适应控制元素，该方法不需要所有智能体都能获得领导者关节速度和加速度的先验信息。由于各智能体的多自由度特性，与m -矩阵理论相关的多智能体系统的矩阵理论结果需要扩展到多度环境中，而不是像最近的标量二重积分结果那样。二自由度机械臂的仿真实例验证了该方法的有效性。

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52nd IEEE Conference on Decision and Control

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