Eman Abuteen scite author profile

This analysis proposes an analytical-numerical approach for providing solutions of a class of nonlinear fractional Klein-Gordon equation subjected to appropriate initial conditions in Caputo sense by using the Fractional Reduced Differential Transform Method (FRDTM). This technique provides the solutions very accurately and efficiently in convergent series formula with easily computable coefficients. The behavior of the approximate series solution for different values of fractional-order ߙ is shown graphically. A comparative study is presented between the FRDTM and Implicit Runge-Kutta approach to illustrate the efficiency and reliability of the proposed technique. Our numerical investigations indicate that the FRDTM is simple, powerful mathematical tool and fully compatible with the complexity of such problems.

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Solving the fractional nonlinear Bloch system using the multi-step generalized differential transform method

Abuteen

Momani

Alawneh

2014

Computers & Mathematics with Applications

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Fitted Reproducing Kernel Method for Solving a Class of Third-Order Periodic Boundary Value Problems

Freihat¹,

Abu-Gdairi²,

Khalil³

et al. 2016

American Journal of Applied Sciences

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Abstract:In this article, the reproducing kernel Hilbert space 4 2 W [0, 1] is employed for solving a class of third-order periodic boundary value problem by using fitted reproducing kernel algorithm. The reproducing kernel function is built to get fast accurately and efficiently series solutions with easily computable coefficients throughout evolution the algorithm under constraint periodic conditions within required grid points. The analytic solution is formulated in a finite series form whilst the truncated series solution is given to converge uniformly to analytic solution. The reproducing kernel procedure is based upon generating orthonormal basis system over a compact dense interval in sobolev space to construct a suitable analytical-numerical solution. Furthermore, experiments results of some numerical examples are presented to illustrate the good performance of the presented algorithm. The results indicate that the reproducing kernel procedure is powerful tool for solving other problems of ordinary and partial differential equations arising in physics, computer and engineering fields.

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Analytical and Numerical Solution for Fractional Gas Dynamic Equations Using Residual Power Series Method

Abuteen

Freihet

2018

SSRN Journal

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Eman Abuteen

Numerical investigation for handling fractional-order Rabinovich–Fabrikant model using the multistep approach

Approximate Series Solution of Nonlinear, Fractional Klein-Gordon Equations Using Fractional Reduced Differential Transform Method

Solving the fractional nonlinear Bloch system using the multi-step generalized differential transform method

Fitted Reproducing Kernel Method for Solving a Class of Third-Order Periodic Boundary Value Problems

Analytical and Numerical Solution for Fractional Gas Dynamic Equations Using Residual Power Series Method

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