基于神经网络的含摩擦和参数不确定柔性关节自适应高精度位置控制

Conference Proceedings. IEEE Canadian Conference on Electrical and Computer Engineering (Cat. No.98TH8341) Pub Date : 1998-05-24 DOI:10.1109/CCECE.1998.682750

E.Y.O. Sidi, P. Sicard, D. Massicotte, S. Lesueur

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引用次数: 5

摘要

将自适应控制与人工神经网络相结合，提出了柔性关节的动态位置控制方法。建立了包含库仑摩擦和静摩擦的柔性关节模型，并用人工神经网络表示。控制策略基于双环策略。外部负载状态反馈用于计算期望负载转矩和电机状态。采用电机内部状态反馈回路对电机进行控制。两个回路都采用摩擦前馈补偿。控制器被表示为一个人工神经网络，系统参数是输出层的权重。参数辨识采用递推最小二乘算法实现。仿真结果表明，该控制器能有效抑制振动。

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Adaptive high precision position control for a flexible joint with friction and parameter uncertainties using neural networks

Dynamic position-control of a flexible joint is proposed by applying adaptive control and artificial neural networks (ANNs). A flexible joint is modeled, including Coulomb and static frictions and the model is represented as an ANN. The control strategy is based on a dual loop strategy. An outer load state feedback is used to compute desired load torque and motor state. An inner motor state feedback loop is used to control the motor. Both loops use feedforward compensation of friction. The controllers are represented as an ANN, the system parameters being the weights of the output layer. Parameter identification is achieved using the recursive least squares algorithm. Simulation results show that the proposed controller can suppress vibrations.

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Conference Proceedings. IEEE Canadian Conference on Electrical and Computer Engineering (Cat. No.98TH8341)

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