A high‐order finite difference method for 1D nonhomogeneous heat equations

Lin, Yuan; Gao, Xuejun; Xiao, Mingqing

doi:10.1002/num.20345

Cited by 10 publications

(12 citation statements)

References 22 publications

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“…In [2], the authors presented a sixth order approximation for the second order derivative together with the constant boundary conditions. To this end, we have…”

Section: O(τ 6 + H 6 ) Finite Difference Methodsmentioning

confidence: 99%

“…The (3, 3) Padé approximation [29] is employed to get sixth order accuracy for temporal variable e Z = 120 -60Z + 12Z 2 -Z 3 -1 120 + 60Z + 12Z 2…”

Section: O(τ 6 + H 6 ) Finite Difference Methodsmentioning

confidence: 99%

“…Consider the following two-dimensional linear parabolic equation: Many efforts have been made to the development of accurate and stable methods for the numerical solution of (1) [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19]. Various high order methods [1-4, 6-9, 11-19] have been proposed.…”

Section: Introductionmentioning

confidence: 99%

“…They obtained two schemes with third and fifth order accuracy in time, respectively. Liu et al [21] used a similar strategy, (2,2) and (3,3) Padé approximations for the time discretization and C 3 quartic spline approximation for space discretization, to get two higher order difference schemes for the one-dimensional linear hyperbolic equation. Zhang [23] provided a (3, 3) Padé approximation method for solving space fractional Fokker-Planck equations.…”

Section: Introductionmentioning

confidence: 99%

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High order locally one-dimensional methods for solving two-dimensional parabolic equations

Chen

2018

Adv Differ Equ

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Based on the locally one-dimensional strategy, we propose two high order finite difference schemes for solving two-dimensional linear parabolic equations. In the first method, fourth order approximation in space and (2, 2) Padé formula in time are considered. These lead to a fourth order finite difference scheme in both space and time. For the second method, we employ sixth order approximation in space and (3, 3) Padé formula in time. This yields a novel sixth order scheme in both space and time. The methods are proved to be unconditionally stable, and the Sheng-Suzuki barrier is successfully avoided. Numerical experiments are given to illustrate our conclusions as well as computational effectiveness.

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“…In [2], the authors presented a sixth order approximation for the second order derivative together with the constant boundary conditions. To this end, we have…”

Section: O(τ 6 + H 6 ) Finite Difference Methodsmentioning

confidence: 99%

“…The (3, 3) Padé approximation [29] is employed to get sixth order accuracy for temporal variable e Z = 120 -60Z + 12Z 2 -Z 3 -1 120 + 60Z + 12Z 2…”

Section: O(τ 6 + H 6 ) Finite Difference Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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High order locally one-dimensional methods for solving two-dimensional parabolic equations

Chen

2018

Adv Differ Equ

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“…The main advantage of semi-analytical methods, compared with other methods, is based on the fact that they can be conveniently applied to solve various complicated problems. Several numerical and analytical methods including non-polynomial cubic spline methods, finite difference, the Laplace decomposition method, the homotopy perturbation transform method, variational iteration methods, the Adomian decomposition method and the homogeneous Adomian decomposition method have been developed for solving linear or nonlinear non-homogeneous partial differential equations, see [1][2][3][4][5][6][7]. HPM, ADM, and VIM methods can be used to solve the non-homogeneous variable coefficient partial differential equations with accurate approximation, but this approximation is acceptable only for a small range [7], because, boundary conditions in one dimension are satisfied via these methods.…”

Section: Introductionmentioning

confidence: 99%

On the coupling of the homotopy perturbation method and Laplace transformation

Madani¹,

Fathizadeh²,

Khan³

et al. 2011

Mathematical and Computer Modelling

154

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a b s t r a c tIn this paper, a Laplace homotopy perturbation method is employed for solving onedimensional non-homogeneous partial differential equations with a variable coefficient. This method is a combination of the Laplace transform and the Homotopy Perturbation Method (LHPM). LHPM presents an accurate methodology to solve non-homogeneous partial differential equations with a variable coefficient. The aim of using the Laplace transform is to overcome the deficiency that is mainly caused by unsatisfied conditions in other semi-analytical methods such as HPM, VIM, and ADM. The approximate solutions obtained by means of LHPM in a wide range of the problem's domain were compared with those results obtained from the actual solutions, the Homotopy Perturbation Method (HPM) and the finite element method. The comparison shows a precise agreement between the results, and introduces this new method as an applicable one which it needs fewer computations and is much easier and more convenient than others, so it can be widely used in engineering too.

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Numerical methods for weak solution of wave equation with van der Pol type nonlinear boundary conditions

Liu

Sun

et al. 2015

Numerical Methods Partial

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We develop computational methods for solving wave equation with van der Pol type nonlinear boundary conditions under the framework of weak solutions. Based on the wave reflection on the boundaries, we first solve the Riemann invariants by constructing two iteration mappings, and then show that the weak solution can be obtained by the integration of the Riemann invariants on the boundaries. If the compatible conditions are not satisfied or only hold with a low degree, a high-order integration method is developed for the numerical solution. When the initial condition is sufficiently smooth and compatible conditions hold with a sufficient degree, we establish a sixth-order finite difference scheme, which only needs to solve a linear system at any given time instance. Numerical experiments are provided to demonstrate the effectiveness of the proposed approaches. w 1 (0) = −ηw 0 (0), w 1 (1) = αw 0 (1) − 3βw 2 1 (1)w 0 (1).(1.4)Numerical Methods for Partial Differential Equations

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A high‐order finite difference method for 1D nonhomogeneous heat equations

Cited by 10 publications

References 22 publications

High order locally one-dimensional methods for solving two-dimensional parabolic equations

High order locally one-dimensional methods for solving two-dimensional parabolic equations

On the coupling of the homotopy perturbation method and Laplace transformation

Numerical methods for weak solution of wave equation with van der Pol type nonlinear boundary conditions

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