Observer-based adaptive neural network control design for projective synchronization of uncertain chaotic systems

Boubakir, Ahsene; Labiod, Salim

doi:10.1177/10775463221101935

Cited by 11 publications

(5 citation statements)

References 60 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In addition, with the continuous development of computer technology and control theory, the design methods and application scope of nonlinear interference observers are also expanding. For example, new types of nonlinear interference observers, such as neural network-based nonlinear interference observers [16] and fuzzy logic-based nonlinear interference observers [17], have been proposed, further improving the performance and application scope of nonlinear interference observers.…”

Section: Introductionmentioning

confidence: 99%

Finite-time Neural Network Adaptive Sliding Mode Control of Fractional-Order Chaotic Systems With Disturbance Observer And Fractional Robust Differentiator

Cui,

Zhao

2024

Preprint

View full text Add to dashboard Cite

This paper proposes a neural network adaptive sliding mode control scheme with a fractional-order disturbance observer and a robust differentiator for fractional-order chaotic systems with uncertain functions and random noise. The solution combines fractional-order differential controllers, gradient descent neural networks, and fractional-order disturbance observer techniques. A gradient descent neural network handles uncertain nonlinear functions, while fractional-order disturbance observers are presented to solve unexpected noise problems. On the premise that the above problems are solved, the state vector is used as the original signal, the ideal function as the tracking signal, and the design error function as the sliding mode surface. Meanwhile, in order to eliminate the vibration caused by the sliding mode functions, a fractional order robust differential observer is introduced in the estimation error. Adaptive rates are introduced in the design of the controller so that the control converges to a small interval in a finite time.

show abstract

Section: Introductionmentioning

confidence: 99%

Finite-time Neural Network Adaptive Sliding Mode Control of Fractional-Order Chaotic Systems With Disturbance Observer And Fractional Robust Differentiator

Cui,

Zhao

2024

Preprint

View full text Add to dashboard Cite

show abstract

“…Chaotic behavior is an extremely complex nonlinear phenomenon that can be noticed in many real-world applications (Tlelo-Cuautle et al, 2020). This behavior can be demonstrated by chaotic systems which are recognized by delivering infinite and unstable periodical motions, bounded phase space trajectories, and extreme sensitivity to small variations of initial conditions (Boubakir and Labiod, 2022). Due to this sensitivity, a chaotic system is committed to deliver different behaviors for any variations of initial conditions.…”

Section: Introductionmentioning

confidence: 99%

Fuzzy L1 adaptive controller for chaos synchronization of uncertain fractional-order chaotic systems with input nonlinearities

Boulham

Boubakir

Labiod

2023

Transactions of the Institute of Measurement and Control

Self Cite

View full text Add to dashboard Cite

This research work proposes a fuzzy fractional-order [Formula: see text] adaptive controller to deal with projective chaos synchronization problems for a general class of uncertain fractional-order chaotic systems subject to unknown input nonlinearities (dead-zone and sector nonlinearities). The suggested control architecture includes a fractional-order sliding surface, a fuzzy system, and an [Formula: see text] adaptive controller. The latter consists of a predictor, a control law, and its adaptive mechanism. The fuzzy system takes the role of an online estimator for system nonlinear uncertain functions which helps in the handling of the input nonlinearities. A designed low-pass filter is placed within the input channel of the [Formula: see text] adaptive controller to ensure that the control loop is decoupled from the estimation loop, which preserves response robustness along with improving transient performances. Finally, the closed-loop stability is rigorously proved, and the acquired results are demonstrated by two simulation examples as well as a comparative study.

show abstract

“…In 1990, the OGY method was developed to realize the control of chaos (Ott et al, 1990). Later, researchers developed many methods to control chaotic behavior, such as active (Agrawal et al, 2012), passive (Kuntanapreeda and Sangpet, 2012), time-delay feedback (Ge et al, 2014), linear feedback (Sun et al, 2009), sliding-mode (Li and Liu, 2010), nonlinear control (Boubakir and Labiod, 2022; Din et al, 2021; Kizmaz et al, 2019), and linear quadratic regulator-based control (Alexander et al, 2023). Among the nonlinear control methods, sliding mode control (SMC) has superb advantages, such as being robust against disturbances, sensor noises, and ensuring well-tracking dynamics.…”

Section: Introductionmentioning

confidence: 99%

Fractional-Order sliding mode control of a 4D memristive chaotic system

Gokyildirim

Çalgan

Demirtaş

2023

Journal of Vibration and Control

View full text Add to dashboard Cite

Chaotic systems depict complex dynamics, thanks to their nonlinear behaviors. With recent studies on fractional-order nonlinear systems, it is deduced that fractional-order analysis of a chaotic system enriches its dynamic behavior. Therefore, the investigation of the chaotic behavior of a 4D memristive Chen system is aimed in this study by taking the order of the system as fractional. The nonlinear behavior of the system is observed numerically by comparing the fractional-order bifurcation diagrams and Lyapunov Exponents Spectra with 2D phase portraits. Based on these analyses, two different fractional orders (i.e., q = 0.948 and q = 0.97) are determined where the 4D memristive system shows chaotic behavior. Furthermore, a single state fractional-order sliding mode controller (FOSMC) is designed to maintain the states of the fractional-order memristive chaotic system on the equilibrium points. Then, control method results are obtained by both numerical simulations and different illustrative experiments of microcontroller-based realization. As expected, voltage outputs of the microcontroller-based realization are in good agreement with the time series of numerical simulations.

show abstract

Observer-based adaptive neural network control design for projective synchronization of uncertain chaotic systems

Cited by 11 publications

References 60 publications

Finite-time Neural Network Adaptive Sliding Mode Control of Fractional-Order Chaotic Systems With Disturbance Observer And Fractional Robust Differentiator

Finite-time Neural Network Adaptive Sliding Mode Control of Fractional-Order Chaotic Systems With Disturbance Observer And Fractional Robust Differentiator

Fuzzy L1 adaptive controller for chaos synchronization of uncertain fractional-order chaotic systems with input nonlinearities

Fractional-Order sliding mode control of a 4D memristive chaotic system

Contact Info

Product

Resources

About