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Design of CNF-based nonlinear integral sliding surface for matched uncertain linear systems with multiple state-delays
by
Mobayen, Saleh
in
Automotive Engineering
/ Classical Mechanics
/ Control
/ Control methods
/ Control systems
/ Control theory
/ Damping ratio
/ Dynamical Systems
/ Engineering
/ Feedback control
/ Integrals
/ Linear systems
/ Mechanical Engineering
/ Nonlinear control
/ Nonlinear dynamics
/ Nonlinear feedback
/ Nonlinear systems
/ Nonlinearity
/ Original Paper
/ Sliding mode
/ Sliding mode control
/ Stability
/ Surface matching
/ Vibration
2014
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Design of CNF-based nonlinear integral sliding surface for matched uncertain linear systems with multiple state-delays
by
Mobayen, Saleh
in
Automotive Engineering
/ Classical Mechanics
/ Control
/ Control methods
/ Control systems
/ Control theory
/ Damping ratio
/ Dynamical Systems
/ Engineering
/ Feedback control
/ Integrals
/ Linear systems
/ Mechanical Engineering
/ Nonlinear control
/ Nonlinear dynamics
/ Nonlinear feedback
/ Nonlinear systems
/ Nonlinearity
/ Original Paper
/ Sliding mode
/ Sliding mode control
/ Stability
/ Surface matching
/ Vibration
2014
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Do you wish to request the book?
Design of CNF-based nonlinear integral sliding surface for matched uncertain linear systems with multiple state-delays
by
Mobayen, Saleh
in
Automotive Engineering
/ Classical Mechanics
/ Control
/ Control methods
/ Control systems
/ Control theory
/ Damping ratio
/ Dynamical Systems
/ Engineering
/ Feedback control
/ Integrals
/ Linear systems
/ Mechanical Engineering
/ Nonlinear control
/ Nonlinear dynamics
/ Nonlinear feedback
/ Nonlinear systems
/ Nonlinearity
/ Original Paper
/ Sliding mode
/ Sliding mode control
/ Stability
/ Surface matching
/ Vibration
2014
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Design of CNF-based nonlinear integral sliding surface for matched uncertain linear systems with multiple state-delays
Journal Article
Design of CNF-based nonlinear integral sliding surface for matched uncertain linear systems with multiple state-delays
2014
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Overview
This paper presents an approach of achieving high performance and robustness for matched uncertain multi-input multi-output linear systems with external disturbances and multiple state-delays, which are often encountered in practice and are frequently the sources of instability. This scheme is based on composite nonlinear feedback and integral sliding mode control methods. The selection of nonlinear function and the existence of sliding mode are two important issues, which have been addressed. The control law is designed to guarantee the existence of the sliding mode around the nonlinear surface, and the damping ratio of the closed-loop system is increased as the output approaches the set-point. Simulation results are presented to show the effectiveness of the proposed method as a promising way for controlling similar nonlinear systems.
Publisher
Springer Netherlands,Springer Nature B.V
Subject
/ Control
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