Broad-learning recurrent Hermite neural control for unknown nonlinear systems

Broad-learning recurrent Hermite neural control for unknown nonlinear systems

The broad-learning systems (BLS) with advance control theories have been studied, but found to have two disadvantages: one is that the calculations are too complicated and the other is that the convergence time cannot be guaranteed. In order to mitigate the high computational loading, this study pro...

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Bibliographic Details
Published in:Knowledge-based systems Vol. 242; p. 108263
Main Authors: Hsu, Chun-Fei, Chen, Bo-Rui, Wu, Bing-Fei
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 22-04-2022
Elsevier Science Ltd
Subjects:
Broad-learning system
Control systems
Controllers
Convergence
Finite-time convergence
Learning
Liapunov functions
Neural networks
Nonlinear control
Nonlinear systems
Parameter learning
Recurrent neural network
Robust control
Stability analysis
System dynamics
Systems stability
Tracking control
Tracking errors
Parameter learning
Stability analysis
Recurrent neural network
Broad-learning system
Finite-time convergence
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Summary:The broad-learning systems (BLS) with advance control theories have been studied, but found to have two disadvantages: one is that the calculations are too complicated and the other is that the convergence time cannot be guaranteed. In order to mitigate the high computational loading, this study proposes a broad-learning Hermite neural network (BHNN), which has the capability of dynamic mapping and reduces the structural complexity of neural network. Meanwhile, a broad-learning recurrent Hermite neural control (BRHNC) system is proposed while maintaining finite-time stability to speed up the tracking error convergence. The proposed BRHNC system comprises two controllers: a recurrent broad controller that utilizes a BHNN to approximate on-line an ideal finite-time controller and a robust exponential controller that ensures system stability through a Lyapunov function. Meanwhile, the BHNN’s full-tuned parameter learning laws are developed to increase the approximating capacity, learning capacity and accuracy using gradient descent method. Finally, simulation and experimental results show that the BRHNC system has good control, tracking and disturbance rejection properties, while the BRHNC system requires no prior knowledge about the system dynamics.
ISSN:0950-7051
1872-7409
DOI:10.1016/j.knosys.2022.108263