Lai, G.; Deng, G.; Yang, W.; Wang, X.; Su, X. Tracking Control of Uncertain Neural Network Systems with Preisach Hysteresis Inputs: A New Iteration-Based Adaptive Inversion Approach. Actuators2023, 12, 341.
Lai, G.; Deng, G.; Yang, W.; Wang, X.; Su, X. Tracking Control of Uncertain Neural Network Systems with Preisach Hysteresis Inputs: A New Iteration-Based Adaptive Inversion Approach. Actuators 2023, 12, 341.
Lai, G.; Deng, G.; Yang, W.; Wang, X.; Su, X. Tracking Control of Uncertain Neural Network Systems with Preisach Hysteresis Inputs: A New Iteration-Based Adaptive Inversion Approach. Actuators2023, 12, 341.
Lai, G.; Deng, G.; Yang, W.; Wang, X.; Su, X. Tracking Control of Uncertain Neural Network Systems with Preisach Hysteresis Inputs: A New Iteration-Based Adaptive Inversion Approach. Actuators 2023, 12, 341.
Abstract
To describe the hysteresis nonlinearities in smart actuators, numerous models have been presented in the literature, among which the Preisach operator would be the most effective one due to its capability in capturing multi-loop or sophisticated hysteresis curves. When such an operator is coupled with uncertain nonlinear dynamics, especially in noncanonical form, it is a challenging problem to develop techniques to cancel out the hysteresis effects, and at the same time achieve asymptotic tracking performance. To resolve this problem, in this paper, we investigate the problem of iterative inverse-based adaptive control for an uncertain noncanonical nonlinear systems with unknown input Preiasch hysteresis, and a new adaptive version of the closest match algorithm is proposed to compensate for the Preisach hysteresis. With our scheme, the stability and convergence of the closed-loop system can be established. The effectiveness of the proposed control scheme is illustrated by simulation and experiment results.
Keywords
Adaptive control; neural networks; stability analysis; piezoactuators; noncanonical nonlinear systems
Subject
Engineering, Automotive Engineering
Copyright:
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