Synchronization of Fractional-Order Delayed Neural Networks Using Dynamic-Free Adaptive Sliding Mode Control

Roohi, Majid; Zhang, Chongqi; Taheri, Mostafa; Basse-O’Connor, Andreas

doi:10.3390/fractalfract7090682

Cited by 20 publications

(5 citation statements)

References 45 publications

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“…The importance of fractional-order chaotic systems lies in their applications in various areas and fields, such as fractional evolution hemivariational inequalities generated by non-instantaneous impulses, which was examined in [19]. In [20], an innovative approach to the encryption of colour images was proposed, where the algorithm was based on extended DNA coding, the Zig-Zag transform, and a fractional-order laser system [21]. Other notable works in this area include "Achieving Superior Multi-Image Encryption Through the Use of Recently Conceived Fractional-Order 3D Lorenz Chaotic System and 2D Discrete Polynomial Hyper-Chaotic Map" [22] and "Fragmentary Fractional Order Systems: Modeling and Initialization Using the Infinite State Representation" [23].…”

Section: Introductionmentioning

confidence: 99%

Real-Time Synchronisation of Multiple Fractional-Order Chaotic Systems: An Application Study in Secure Communication

Nail,

Atoussi,

Saadi

et al. 2024

Fractal Fract

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In this paper, we use two Fractional-Order Chaotic Systems (FOCS)—one for the sender and one for the receiver—to determine the optimal synchronisation for a secure communication technique. With the help of the Step-By-Step Sliding-Mode Observer (SBS-SMO), this synchronisation is accomplished. An innovative optimisation method, known as the artificial Harris hawks optimisation (HHO), was employed to enhance the observer’s performance. This method eliminates the random parameter selection process and instead selects the optimal values for the observer. In a short amount of time, the secret message that could have been in the receiver portion (signal, voice, etc.) was successfully recovered using the proposed scheme. The experimental validation of the numerical results was carried out with the assistance of an Arduino microcontroller and several electronic components. In addition, the findings of the experiments were compared with the theoretical calculations, revealing a satisfactory level of agreement.

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Section: Introductionmentioning

confidence: 99%

Real-Time Synchronisation of Multiple Fractional-Order Chaotic Systems: An Application Study in Secure Communication

Nail,

Atoussi,

Saadi

et al. 2024

Fractal Fract

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“…Literature [31] is the first to consider the tank bidirectional stabilization system with a fully electric actuator as a fuzzy mechanical system with inequality constraints and conduct an optimization design after proposing an error-controllable control strategy. In the Literature [32], a dynamic-free adaptive sliding mode control (adaptive-SMC) methodology for the synchronization of a specific class of chaotic delayed fractional-order neural network systems in the presence of input saturation is proposed. Literature [33] addresses the attitude-tracking control problem of multiple rigid bodies in the presence of completely unknown inertial information.…”

Section: Introductionmentioning

confidence: 99%

Adaptive Fuzzy Sliding Mode Control and Dynamic Modeling of Flap Wheel Polishing Force Control System

Hong,

Zhou,

2024

Applied Sciences

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Polishing force is one of the key process parameters in the polishing process of blisk blades, and its control accuracy will affect the surface quality and processing accuracy of the workpiece. The contact mechanism between the polishing surface and flap wheel was analyzed, and the calculation model of the polishing force and nonlinear dynamic model of the polishing force control system was established. Considering the influence of friction characteristics, parameter perturbation, and nonlinear dead zone on the control accuracy of the polishing force system, an adaptive fuzzy sliding mode controller (AFSMC) was designed. AFSMC uses a fuzzy system to adaptively approximate the nonlinear function terms in the sliding mode control law, adopts an exponential approach law in the switching control part of the sliding mode control (SMC), and designs the adaptive law for adjustable parameters in the fuzzy system based on the Lyapunov Theorem. Simulation and experimental results show that the designed AFSMC has a fast dynamic response, strong anti-interference ability, and high control accuracy, and it can reduce SMC high-frequency chatter. Polishing experiments show that compared with traditional PID, AFSMC can improve the form and position accuracy of the blade by 42% and reduce the surface roughness by 50%.

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“…Fractional order operators have broadened the concept of integer order operators [5]. In the last ten years, PDEs of fractional order have attracted the remarkable attention of the research community due to their ability to model various problems, such as neural networks [6], optimal voltage controllers for electronic vehicle charging stations [7], robotics [8], optimal controls for impulsive systems [9], hydrology [10], medical sciences [11], and many others [12].…”

Section: Introductionmentioning

confidence: 99%

Numerical Solution of Advection–Diffusion Equation of Fractional Order Using Chebyshev Collocation Method

Ali Shah,

Kamran,

Boulila

et al. 2023

Fractal Fract

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This work presents a highly accurate method for the numerical solution of the advection–diffusion equation of fractional order. In our proposed method, we apply the Laplace transform to handle the time-fractional derivative and utilize the Chebyshev spectral collocation method for spatial discretization. The primary motivation for using the Laplace transform is its ability to avoid the classical time-stepping scheme and overcome the adverse effects of time steps on numerical accuracy and stability. Our method comprises three primary steps: (i) reducing the time-dependent equation to a time-independent equation via the Laplace transform, (ii) employing the Chebyshev spectral collocation method to approximate the solution of the transformed equation, and (iii) numerically inverting the Laplace transform. We discuss the convergence and stability of the method and assess its accuracy and efficiency by solving various problems in two dimensions.

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Synchronization of Fractional-Order Delayed Neural Networks Using Dynamic-Free Adaptive Sliding Mode Control

Cited by 20 publications

References 45 publications

Real-Time Synchronisation of Multiple Fractional-Order Chaotic Systems: An Application Study in Secure Communication

Real-Time Synchronisation of Multiple Fractional-Order Chaotic Systems: An Application Study in Secure Communication

Adaptive Fuzzy Sliding Mode Control and Dynamic Modeling of Flap Wheel Polishing Force Control System

Numerical Solution of Advection–Diffusion Equation of Fractional Order Using Chebyshev Collocation Method

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