Adaptive full order sliding mode control for electronic throttle valve system with fixed time convergence using extreme learning machine

Adaptive full order sliding mode control for electronic throttle valve system with fixed time convergence using extreme learning machine

This paper proposes a novel extreme learning machine (ELM)-based fixed time adaptive trajectory control for electronic throttle valve system with uncertain dynamics and external disturbances. The developed control strategy consists of a recursive full order terminal sliding mode structure based on t...

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Veröffentlicht in:Neural computing & applications 2022-04, Vol.34 (7), p.5241-5253
Hauptverfasser: Hu, Youhao, Wang, Hai, Yazdani, Amirmehdi, Man, Zhihong
Format: Artikel
Sprache:eng
Schlagworte:
Adaptive algorithms
Adaptive control
Artificial Intelligence
Artificial neural networks
Closed loop systems
Computational Biology/Bioinformatics
Computational Science and Engineering
Computer Science
Control valves
Convergence
Data Mining and Knowledge Discovery
Feedback control
Image Processing and Computer Vision
Machine learning
Neural networks
Probability and Statistics in Computer Science
S.I: Computational Intelligence-based Control and Estimation in Mechatronic Systems
Sliding mode control
Special Issue on Computational Intelligence-based Control and Estimation in Mechatronic Systems
Trajectory control
Upper bounds
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Zusammenfassung:This paper proposes a novel extreme learning machine (ELM)-based fixed time adaptive trajectory control for electronic throttle valve system with uncertain dynamics and external disturbances. The developed control strategy consists of a recursive full order terminal sliding mode structure based on the bilimit homogeneous property and a lumped uncertainty changing rate upper bound estimator via an adaptive ELM algorithm such that not only the fixed time convergence for both sliding variable and error states can be guaranteed, but also the chattering phenomenon can be suppressed effectively. The stability of the closed-loop system is proved rigorously based on Lyapunov theory. The simulation results are given to verify the superior tracking performance of the proposed control strategy.
ISSN:0941-0643
1433-3058
DOI:10.1007/s00521-021-06365-0