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Approximate Numerical solutions for the nonlinear dispersive shallow water waves as the Fornberg–Whitham model equations

Hijaz Ahmad, Aly R. Seadawy, Abdul Hamid Ganie, Saima Rashid, Tufail A. Khan, Hanaa Abu-Zinadah

2021Results in Physics28 citationsDOIOpen Access PDF

Abstract

The nonlinear partial differential equations having travelling or solitary wave solutions is numerically challenging, in which one of the important type is the Fornberg–Whitham model equation. This article aims to solve the Fornberg–Whitham type equations numerically via the variational iteration algorithm-I (MVIA-I). The MVIA-I gives approximate and exact solutions with easily computable terms to linear and nonlinear PDEs without the linearization or discretization, small perturbation and Adomian polynomials. To assess the precision, reliability and compactness of the recommended algorithm, we have compared the obtained results with the traditional variational iteration method (VIM), homotopy analysis method, reproducing kernel Hilbert space method and Adomian’s decomposition method which reveals that the MVIA-I is computationally attractive, exceptionally productive and is more reliable than the others techniques used in the literature.

Topics & Concepts

Adomian decomposition methodMathematicsDiscretizationNonlinear systemHomotopy analysis methodLinearizationMathematical analysisPartial differential equationApplied mathematicsHilbert spaceHomotopyPhysicsPure mathematicsQuantum mechanicsFractional Differential Equations SolutionsNonlinear Waves and SolitonsDifferential Equations and Numerical Methods
Approximate Numerical solutions for the nonlinear dispersive shallow water waves as the Fornberg–Whitham model equations | Litcius