Differential Quadrature Solutions of the Generalized Burgers–Fisher Equation with a Strong Stability Preserving High-Order Time Integration

Sarı, Murat

doi:10.3390/mca16020477

Cited by 5 publications

(9 citation statements)

References 34 publications

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“…In order to test the accuracy and efficiency of the proposed scheme, comparisons of the obtained results are made with the above exact solution and traditional methods such as [26, (44) 32,35,36]. MATLAB 8.1 has been utilized in this work for simulations.…”

Section: Numerical Experiments and Discussionmentioning

confidence: 99%

“…Ismail et al [24] applied Adomian decomposition method (ADM), Javidi [25] employed modified pseudospectral method, Rashidi et al [26] used homotopy perturbation method (HPM), Khattak [27] employed collocation-based radial basis functions method (CBRBF) and Xu and Xian [28] applied Exp-function method to find the analytic as well as numerical solutions of the generalized Burgers-Fisher equation. Also many other authors used different methods to obtain the analytical and numerical solution of the generalized Burgers-Fisher equation; for example, Zhu and Kang [29] used the B-spline quasi-interpolation method, Zhang and Yan [30] used a lattice Boltzmann model, Sari et al [31] used the compact finite difference method, Sari et al [32] developed the polynomial-based differential quadrature method, Zhang et al [33] used the local discontinuous Galerkin (LDG) methods and Nawaz et al [34] employed optimal homotopy asymptotic method (OHAM).…”

Section: Introductionmentioning

confidence: 99%

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A fourth-order B-spline collocation method for nonlinear Burgers–Fisher equation

2020

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A fourth-order B-spline collocation method has been applied for numerical study of Burgers-Fisher equation, which illustrates many situations occurring in various fields of science and engineering including nonlinear optics, gas dynamics, chemical physics, heat conduction, and so on. The present method is successfully applied to solve the Burgers-Fisher equation taking into consideration various parametric values. The scheme is found to be convergent. Crank-Nicolson scheme has been employed for the discretization. Quasi-linearization technique has been employed to deal with the nonlinearity of equations. The stability of the method has been discussed using Fourier series analysis (von Neumann method), and it has been observed that the method is unconditionally stable. In order to demonstrate the effectiveness of the scheme, numerical experiments have been performed on various examples. The solutions obtained are compared with results available in the literature, which shows that the proposed scheme is satisfactorily accurate and suitable for solving such problems with minimal computational efforts.

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Section: Numerical Experiments and Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A fourth-order B-spline collocation method for nonlinear Burgers–Fisher equation

2020

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“…, 2 can be successively calculated from equation (29). This process is started with the initial condition (12). These coefficients are then substituted in equations (25)-(27) to obtain the approximate solutions at different time levels.…”

Section: Haar Wavelet Methodsmentioning

confidence: 99%

“…The Burgers-Fisher equation which describes the interaction between the reaction mechanism, convection effect, and diffusion transport [6] is considered in this paper. Many numerical schemes have been proposed for obtaining approximate solutions of the Burger-fisher equation [7][8][9][10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Implementation of Wavelet Based Transform for numerical solutions of Partial differential equations

Al-Fayadh¹,

Hazim²

2017

IOSR JM

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“…Many researchers have studied it theoretically and numerically. Because of its strong nonlinearity, it is often used as a model problem to test various numerical methods, where, among others, finite-difference methods [16,23,24], the Adomian decomposition method [17,19] and differential quadrature [22] have been used. Powerful mathematical methods such as the tanh [11,28], extended tanh [10], tanh-coth [29,30], exp-function [31], variational iteration [21], homotopy analysis [2], factorization [12] and spectral collocation [14,18] methods have also been used for this equation.…”

Section: Introductionmentioning

confidence: 99%

An Improved Second-Order Numerical Method for the Generalized Burgers–fisher Equation

Bratsos

2013

ANZIAM J.

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A second-order in time finite-difference scheme using a modified predictor-corrector method is proposed for the numerical solution of the generalized Burgers-Fisher equation. The method introduced, which, in contrast to the classical predictor-corrector method is direct and uses updated values for the evaluation of the components of the unknown vector, is also analysed for stability. Its efficiency is tested for a singlekink wave by comparing experimental results with others selected from the available literature. Moreover, comparisons with the classical method and relevant analogous modified methods are given. Finally, the behaviour and physical meaning of the twokink wave arising from the collision of two single-kink waves are examined.2010 Mathematics subject classification: primary 35K57; secondary 35Q51, 65M06, 65Y10.

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Differential Quadrature Solutions of the Generalized Burgers–Fisher Equation with a Strong Stability Preserving High-Order Time Integration

Cited by 5 publications

References 34 publications

A fourth-order B-spline collocation method for nonlinear Burgers–Fisher equation

A fourth-order B-spline collocation method for nonlinear Burgers–Fisher equation

Implementation of Wavelet Based Transform for numerical solutions of Partial differential equations

An Improved Second-Order Numerical Method for the Generalized Burgers–fisher Equation

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