New unconditionally stable scheme for telegraph equation based on weighted Laguerre polynomials

Zhang, Di; Miao, Xiaoping

doi:10.1002/num.22155

Cited by 8 publications

(4 citation statements)

References 31 publications

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“…As explained in the nal paragraph of Section 3, the element ũp depends on the parameters β j and thus ũp diers in (4.3) and (4.4). We mention that numerical methods for direct problems for the wave and telegraph equations related to the above are [11,14,29,34]. Of course, for the direct problem for the wave equation (4.1), any of the standard numerical methods such as the nite element method (with or without time-discretisation), nite dierences or the boundary element method can be applied although with more eort for mesh generation, see the overview [33].…”

Section: Houbolt Methodsmentioning

confidence: 99%

A fundamental sequences method with time-reduction for one-dimensional lateral Cauchy problems

Borachok,

Chapko,

Johansson

2023

J. App. Num. Analysis

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A fundamental sequences method is derived for the numerical solution of an ill-posed one-dimensional lateral Cauchy problem for a hyperbolic damped wave equation, including as a special case the parabolic heat equation. Either the Laguerre transform or the Houbolt finite difference scheme is applied to reduce the time-dependent lateral Cauchy problem to a sequence of second-order ordinary differential equations (ODEs) with function values and derivatives specified at the right endpoint of a finite space interval. A set of fundamental solutions is constructed, termed a fundamental sequence, to the differential equations. The solution of the obtained ODEs is approximated by a linear combination of elements in the fundamental sequence. Source points are placed outside of the solution interval in space, and by collocating at the endpoints of this interval a sequence of linear equations is obtained for finding the unknown coeficients. Tikhonov regularization is used to render a stable solution to the obtained systems of linear equations. Numerical results both for the parabolic and hyperbolic case confirm the efficiency of the proposed method including noisy data. The presented results complement the higher-dimensional case initiated in our previous researches.

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Section: Houbolt Methodsmentioning

confidence: 99%

A fundamental sequences method with time-reduction for one-dimensional lateral Cauchy problems

Borachok,

Chapko,

Johansson

2023

J. App. Num. Analysis

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“…( 2021 ) used a novel Laguerre neural network with three layers of neurons for solving Black–Scholes equations and proved its high accuracy and superiority over other existing algorithms. Zhang and Miao ( 2017 ) applied weighted LPs to an unconditionally stable scheme for solving one-dimensional telegraph equation.…”

Section: Introductionmentioning

confidence: 99%

Optimal Approximation of Fractional Order Brain Tumor Model Using Generalized Laguerre Polynomials

et al. 2023

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A brain tumor occurs when abnormal cells form within the brain. Glioblastoma (GB) is an aggressive and fast-growing type of brain tumor that invades brain tissue or spinal cord. GB evolves from astrocytic glial cells in the central nervous system. GB can occur at almost any age, but the occurrence increases with advancing age in older adults. Its symptoms may include nausea, vomiting, headaches, or even seizures. GB, formerly known as glioblastoma multiforme, currently has no cure with a high rate of resistance to therapy in clinical treatment. However, treatments can slow tumor progression or alleviate the signs and symptoms. In this paper, a fractional order brain tumor model was considered. The optimal solution of the model was obtained using an optimization method based on operational matrices. The solution to the problem under study was expanded in terms of generalized Laguerre polynomials (GLPs). The study problem was shifted to a system of nonlinear algebraic equations by the use of Lagrange multipliers combined with operational matrices based on GLPs. The analysis of convergence was discussed. In the end, some numerical examples were presented to justify theoretical statements along with the patterns of biological behavior.

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“…Among these equations, the hyperbolic telegraph equation is an important type of hyperbolic partial differential equation commonly used in modeling of mathematical problems such as signal analysis, random walking theory and wave propagation [1]. Many methods have been applied to solve numerically the second order linear hyperbolic telegraph equation, such as the implicit three-level difference scheme [2], the collocation methods based on the thin plate splines, the quartic B-spline, the septic B-spline, the cubic B-spline, the modified cubic B-spline, the extended cubic B-spline and the cubic trigonometric B-spline [3][4][5][6][7][8][9][10][11], the Rothe-Wavelet method [12], the Legendre multiwavelet Galerkin method [13], the Chebyshev tau method [14], the finite difference methods based on the quartic spline functions, the non-polynomial splines and the cubic Hermite interpolation polynomial function [15][16][17], the unconditionally stable parallel difference scheme [18], the boundary integral equation method and the dual reciprocity technique [19], the differential quadrature method [20,21], the Rothe-wavelet-Galerkin method [22], the reduced differential transform method [23], the reproducing Kernel Hilbert space method [24], the sinc-collocation method [25], the Chebyshev wavelets method [26], the meshfree method based on the radial basis functions [1], the polynomial scaling functions method [27], the high-order shifted Gegenbauer pseudospectral method [28], the uniformly convergent Euler matrix method [29], the Euler method [30], the Bessel collocation method [31], the Galerkin method [32] and the adaptive Monte Carlo method …”

Section: Introductionmentioning

confidence: 99%

High order accurate method for the numerical solution of the second order linear hyperbolic telegraph equation

Kirli

Irk

Görgülü

2022

Numerical Methods Partial

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In this study, the Galerkin finite element method is applied to get the numerical solution of the linear telegraph equation by using cubic B‐spline function. Differently from the existing studies, the fourth order one‐step method is used to discretize in time the telegraph equation. The efficiency and accuracy of the proposed method is studied by three examples. The obtained results are shown that the proposed method has a higher accuracy.

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New unconditionally stable scheme for telegraph equation based on weighted Laguerre polynomials

Cited by 8 publications

References 31 publications

A fundamental sequences method with time-reduction for one-dimensional lateral Cauchy problems

A fundamental sequences method with time-reduction for one-dimensional lateral Cauchy problems

Optimal Approximation of Fractional Order Brain Tumor Model Using Generalized Laguerre Polynomials

High order accurate method for the numerical solution of the second order linear hyperbolic telegraph equation

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