On Averaging Principle for Caputo–Hadamard Fractional Stochastic Differential Pantograph Equation

Mouy, Mounia; Boulares, Hamid; Alshammari, Saleh; Alshammari, Mohammad; Laskri, Yamina; Mohammed, Wael W.

doi:10.3390/fractalfract7010031

Cited by 15 publications

(6 citation statements)

References 16 publications

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“…In fact, our work is an important generalization of what is obtained in the reference see [15] The nature of solutions for fractional stochastic differential pantograph equations (FSDPEs) with the ψ-Caputo sense in Euclidean n-dimentional spaces, R n [14,16,17], is of hight interest in many applications. In general, such systems can take the form…”

Section: Introductionmentioning

confidence: 79%

Khasminskii Approach for $$\psi $$-Caputo Fractional Stochastic Pantograph Problem

Alqudah,

Boulares,

Abdalla

et al. 2024

Qual. Theory Dyn. Syst.

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In this manuscript, we study an averaging principle for fractional stochastic pantograph differential equations (FSDPEs) in the $$\psi $$ ψ -sense accompanied by Brownian movement. Under certain assumptions, we are able to approximate solutions for FSPEs by solutions to averaged stochastic systems in the sense of mean square. Analysis of system solutions before and after the average allows extending the classical Khasminskii approach to random fractional differential equations in the sense of $$\psi $$ ψ -Caputo. For clarity, we present at the end an applied example to facilitate the clarification of the theoretical results obtained

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Section: Introductionmentioning

confidence: 79%

Khasminskii Approach for $$\psi $$-Caputo Fractional Stochastic Pantograph Problem

Alqudah,

Boulares,

Abdalla

et al. 2024

Qual. Theory Dyn. Syst.

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“…Several mathematicians have provided several versions of fractional derivatives. The most common are those suggested by Riesz, Riemann-Liouville, Marchaud Grunwald-Letnikov, Erdelyi, Caputo, and Hadamard [30][31][32][33][34]. Traditional derivative formulae, such as the product rule, quotient rule, and chain rule, do not apply to a large number of fractional derivative types.…”

Section: M-truncated Derivativementioning

confidence: 99%

The Analytical Solutions to the Fractional Kraenkel–Manna–Merle System in Ferromagnetic Materials

et al. 2023

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In this article, we examine the Kraenkel–Manna–Merle system (KMMS) with an M-truncated derivative (MTD). Our goal is to obtain rational, hyperbolic, and trigonometric solutions by using the F-expansion technique with the Riccati equation. To our knowledge, no one has studied the exact solutions to the KMMS in the presence/absence of a damping effect with an M-truncated derivative, using the F-expansion technique. The magnetic field propagation in a zero-conductivity ferromagnet is described by the KMMS; hence, solutions to this equation may provide light on several fascinating scientific phenomena. We use MATLAB to display figures in a variety of 3D and 2D formats to demonstrate the influence of the M-truncated derivative on the exact solutions to the KMMS.

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“…As a result, multiple mathematicians proposed several fractional derivatives. The most well-known include those suggested by Riemann-Liouville, Riesz, Caputo, Hadamard, two-scale fractal derivative, He's fractional derivative, Grunwald-Letnikov, Atangana-Baleanu's derivative and M-truncated derivative [12][13][14][15][16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Abundant optical soliton solutions for the stochastic fractional fokas system using bifurcation analysis

Mohammed,

Cesarano,

Elmandouh

et al. 2024

Phys. Scr.

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In this study, the stochastic fractional Fokas system (SFFS) with M-truncated derivatives is considered. A certain wave transformation is applied to convert this system to a one-dimensional conservative Hamiltonian system. Based on the qualitative theory of dynamical systems, the bifurcation and phase portrait are examined. Utilizing the conserved quantity, we construct some new traveling wave solutions for the SFFS. Due to the fact that the Fokas system is used to explain nonlinear pulse transmission in mono-mode optical fibers, the given solutions may be applied to analyze an extensive variety of crucial physical phenomena. To clarify the effects of the M-truncated derivative and Wiener process, the dynamic behaviors of the various obtained solutions are depicted with 3-D and 2-D curves.

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On Averaging Principle for Caputo–Hadamard Fractional Stochastic Differential Pantograph Equation

Cited by 15 publications

References 16 publications

Khasminskii Approach for $$\psi $$-Caputo Fractional Stochastic Pantograph Problem

Khasminskii Approach for $$\psi $$-Caputo Fractional Stochastic Pantograph Problem

The Analytical Solutions to the Fractional Kraenkel–Manna–Merle System in Ferromagnetic Materials

Abundant optical soliton solutions for the stochastic fractional fokas system using bifurcation analysis

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