Chatter-Free Adaptive Control of a Memristor-Based Four-Dimensional Chaotic Oscillator

Chatter-Free Adaptive Control of a Memristor-Based Four-Dimensional Chaotic Oscillator

Memristors have several chaotic dynamic models and have been used successfully in various fields, including secure communication systems, information storage, and artificial neural networks. The memristor-based four-dimensional chaotic (FDMC) systems generate unpredictable and intricate time domain...

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Bibliographic Details
Published in:Arabian journal for science and engineering (2011) Vol. 49; no. 5; pp. 7677 - 7699
Main Authors: Shafiq, Muhammad, Ahmad, Israr
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-05-2024
Springer Nature B.V
Subjects:
Adaptive control
Artificial neural networks
Closed loops
Communications systems
Computer simulation
Disturbances
Dynamic models
Engineering
Feedback control
Humanities and Social Sciences
Information storage
Memristors
multidisciplinary
Nonlinear control
Research Article-Systems Engineering
Robust control
Science
Stability analysis
State variable
Trajectory control
Uncertainty
Chaos stabilization
Hyperchaotic system
Lyapunov stability theory
Nonlinear robust adaptive controller
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Summary:Memristors have several chaotic dynamic models and have been used successfully in various fields, including secure communication systems, information storage, and artificial neural networks. The memristor-based four-dimensional chaotic (FDMC) systems generate unpredictable and intricate time domain signals. Parameter fluctuations in the FDMC system may give birth to chaos, making it difficult to suppress. Stabilizing chaos in the FDMC system improves the circuit’s performance. This paper synthesizes a novel time-efficient chatter-free nonlinear robust adaptive control (NLRAC) technique that stabilizes chaos in the FDMC system affected by time-varying unknown bounded exogenous disturbances and model uncertainties. The proposed NLRAC strategy decimates the time-varying unknown bounded exogenous disturbances and model uncertainties effects; it establishes a faster, smoother state-variable trajectories convergence to the zero vicinity. The theoretical analysis and mathematical proofs are based on the Lyapunov stability technique. Computer simulation results show that the proposed NLRAC technique effectively brings the FDMC system's state-variable trajectories to zero with reduced fluctuations for control input signals and state-variable trajectories. This feedback controller’s attribute enhances closed-loop stability performance, improves precision, and reduces risk overshoot. The paper includes comparative computer simulation results to endorse the proposed controller performance.
ISSN:2193-567X
1319-8025
2191-4281
DOI:10.1007/s13369-023-08587-x