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08-03-2022 | Original Article

An accurate localized meshfree collocation technique for the telegraph equation in propagation of electrical signals

Authors: O. Nikan, Z. Avazzadeh, J. A. Tenreiro Machado, M. N. Rasoulizadeh

Published in: Engineering with Computers | Issue 3/2023

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Abstract

This paper presents an accurate localized meshfree collocation technique for the approximate solution of the second-order two-dimensional telegraph model. This model is an useful description of the propagation of electrical signals in a transmission line as well as wave phenomena. The proposed algorithm approximates the unknown solution in two steps. First, the discretization of time variable is accomplished by the Crank–Nicolson finite difference. Additionally, the unconditional stability and the convergence of the temporal semi-discretization approach are analysed with the help of the energy method in an appropriate Sobolev space. Second, the discretization of the spatial variable and its partial derivatives is obtained by the localized radial basis function partition of unity collocation method. The global collocation methods pose a considerable computational burden due to the calculation of the dense algebraic system. With the proposed approach, the domain is decomposed into several subdomains via a kernel approximation on every local domain. Therefore, it is possible to make the algebraic system more sparse and, consequently, to achieve a small condition number and a limited computational cost. Three numerical examples support the theoretical study and highlight the effectiveness of the method.

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Adler RB, Chu LJ, Fano RM (1960) Electromagnetic energy transmission and radiation. Students’ Q J 31(122):123–124MATH

Ahmad I, Ahmad H, Abouelregal AE, Thounthong P, Abdel-Aty M (2020) Numerical study of integer-order hyperbolic telegraph model arising in physical and related sciences. Eur Phys J Plus 135(9):1–14

Babuška I, Melenk JM (1997) The partition of unity method. Int J Numer Meth Eng 40(4):727–758MathSciNetMATH

Banasiak J, Mika JR (1998) Singularly perturbed telegraph equations with applications in the random walk theory. J Appl Math Stoch Anal 11(1):9–28MathSciNetMATH

Cavoretto R, De Rossi A (2020) Error indicators and refinement strategies for solving Poisson problems through a RBF partition of unity collocation scheme. Appl Math Comput 369:124824MathSciNetMATH

Cavoretto R, De Rossi A, Perracchione E (2015) Partition of unity interpolation on multivariate convex domains. Int J Model Simul Sci Comput 6(04):1550034

Cavoretto R, De Rossi A, Perracchione E (2016) Efficient computation of partition of unity interpolants through a block-based searching technique. Comput Math Appl 71(12):2568–2584MathSciNetMATH

Cavoretto R, De Rossi A, Perracchione E (2018) Optimal selection of local approximants in RBF-PU interpolation. J Sci Comput 74(1):1–22MathSciNetMATH

Chipman RA (1968) Schaum’s outline of transmission lines. McGraw-Hill, New York

10.

Dehghan M, Ghesmati A (2010) Combination of meshless local weak and strong (MLWS) forms to solve the two dimensional hyperbolic telegraph equation. Eng Anal Bound Elem 34(4):324–336MathSciNetMATH

11.

Dehghan M, Salehi R (2012) A method based on meshless approach for the numerical solution of the two-space dimensional hyperbolic telegraph equation. Math Methods Appl Sci 35(10):1220–1233MathSciNetMATH

12.

Dehghan M, Shafieeabyaneh N (2021) Local radial basis function-finite-difference method to simulate some models in the nonlinear wave phenomena: regularized long-wave and extended Fisher-Kolmogorov equations. Eng Comput 37(4):1159–1179

13.

Devi V, Maurya RK, Singh S, Singh VK (2020) Lagrange’s operational approach for the approximate solution of two-dimensional hyperbolic telegraph equation subject to dirichlet boundary conditions. Appl Math Comput 367:124717MathSciNetMATH

14.

Fasshauer GE (2007) Meshfree approximation methods with MATLAB, vol 6. World Scientific, SingaporeMATH

15.

Ghehsareh HR, Zaghian A, Raei M (2018) A local weak form meshless method to simulate a variable order time-fractional mobile-immobile transport model. Eng Anal Bound Elem 90:63–75MathSciNetMATH

16.

Gu Y (2005) Meshfree methods and their comparisons. Int J Comput Methods 2(04):477–515MATH

17.

Habibirad A, Roohi R, Hesameddini E, Heydari M (2021) A reliable algorithm to determine the pollution transport within underground reservoirs: implementation of an efficient collocation meshless method based on the moving Kriging interpolation. Eng Comput:1–15

18.

Haghighi D, Abbasbandy S, Shivanian E, Dong L, Atluri SN (2022) The Fragile Points Method (FPM) to solve two-dimensional hyperbolic telegraph equation using point stiffness matrices. Eng Anal Bound Elem 134:11–21MathSciNetMATH

19.

Heryudono A, Larsson E, Ramage A, von Sydow L (2016) Preconditioning for radial basis function partition of unity methods. J Sci Comput 67(3):1089–1109MathSciNetMATH

20.

Hesameddini E, Asadolahifard E (2016) A new spectral Galerkin method for solving the two dimensional hyperbolic telegraph equation. Comput Math Appl 72(7):1926–1942MathSciNetMATH

21.

Heydari MH, Hooshmandasl M, Ghaini FM (2014) A new approach of the Chebyshev wavelets method for partial differential equations with boundary conditions of the telegraph type. Appl Math Model 38(5–6):1597–1606MathSciNetMATH

22.

Jiwari R, Pandit S, Mittal R (2012) A differential quadrature algorithm to solve the two dimensional linear hyperbolic telegraph equation with Dirichlet and neumann boundary conditions. Appl Math Comput 218(13):7279–7294MathSciNetMATH

23.

Jordan P, Puri A (1999) Digital signal propagation in dispersive media. J Appl Phys 85(3):1273–1282

24.

Kumar D, Singh J, Kumar S (2014) Analytic and approximate solutions of space-time fractional telegraph equations via Laplace transform. WJST 11(8):711–728

25.

Lakestani M, Saray BN (2010) Numerical solution of telegraph equation using interpolating scaling functions. Comput Math Appl 60(7):1964–1972MathSciNetMATH

26.

Lin J, Chen F, Zhang Y, Lu J (2019) An accurate meshless collocation technique for solving two-dimensional hyperbolic telegraph equations in arbitrary domains. Eng Anal Bound Elem 108:372–384MathSciNetMATH

27.

Liu GR, Gu YT (2005) An introduction to meshfree methods and their programming. Springer, Berlin

28.

Lock CGJ, Greeff J, Joubert S (2007) Modelling of telegraph equations in transmission lines. Ph.D. thesis, Tshwane University of Technology

29.

Ma W, Zhang B, Ma H (2016) A meshless collocation approach with barycentric rational interpolation for two-dimensional hyperbolic telegraph equation. Appl Math Comput 279:236–248MathSciNetMATH

30.

Machado J, Jesus I (2004) A suggestion from the past? Fract Calcul Appl Anal 7(4):403–407MATH

31.

Melenk JM, Babuška I (1996) The partition of unity finite element method: basic theory and applications. Comput Methods Appl Mech Eng 139(1–4):289–314MathSciNetMATH

32.

Mishra AK, Kumar S, Shukla A (2021) Numerical approximation of fractional telegraph equation via legendre collocation technique. Int J Appl Comput Math 7(5):1–27MathSciNetMATH

33.

Mittal R, Bhatia R (2014) A numerical study of two dimensional hyperbolic telegraph equation by modified B-spline differential quadrature method. Appl Math Comput 244:976–997MathSciNetMATH

34.

Nikan O, Avazzadeh Z (2021) Coupling of the Crank-Nicolson scheme and localized meshless technique for viscoelastic wave model in fluid flow. J Comput Appl Math 1:113695MathSciNetMATH

35.

Nikan O, Avazzadeh Z, Rasoulizadeh M (2021) Soliton solutions of the nonlinear sine-Gordon model with Neumann boundary conditions arising in crystal dislocation theory. Nonlinear Dynam:1–31

36.

Oruç Ö (2018) A numerical procedure based on Hermite wavelets for two-dimensional hyperbolic telegraph equation. Eng Comput 34(4):741–755

37.

Oruç Ö (2021) A local radial basis function-finite difference (RBF-FD) method for solving 1D and 2D coupled Schrödinger–Boussinesq (SBq) equations. Eng Anal Bound Elem 129:55–66MathSciNetMATH

38.

Oruç Ö (2021) A radial basis function finite difference (RBF-FD) method for numerical simulation of interaction of high and low frequency waves: Zakharov-Rubenchik equations. Appl Math Comput 394:125787MathSciNetMATH

39.

Rasoulizadeh M, Ebadi M, Avazzadeh Z, Nikan O (2021) An efficient local meshless method for the equal width equation in fluid mechanics. Eng Anal Bound Elem 131:258–268MathSciNetMATH

40.

Rasoulizadeh M, Nikan O, Avazzadeh Z (2021) The impact of LRBF-FD on the solutions of the nonlinear regularized long wave equation. Math Sci 15:365–376MathSciNetMATH

41.

Rostamy D, Emamjome M, Abbasbandy S (2017) A meshless technique based on the pseudospectral radial basis functions method for solving the two-dimensional hyperbolic telegraph equation. Eur Phys J Plus 132(6):1–11

42.

Saadatmandi A, Dehghan M (2010) Numerical solution of hyperbolic telegraph equation using the Chebyshev tau method. Num Methods Partial Differ Equ 26(1):239–252MathSciNetMATH

43.

Safdari-Vaighani A, Heryudono A, Larsson E (2015) A radial basis function partition of unity collocation method for convection-diffusion equations arising in financial applications. J Sci Comput 64(2):341–367MathSciNetMATH

44.

Sarra SA (2012) A local radial basis function method for advection-diffusion-reaction equations on complexly shaped domains. Appl Math Comput 218(19):9853–9865MathSciNetMATH

45.

Shanak H, Florea O, Alshaikh N, Jihad A (2020) Mathematical and numerical approach for telegrapher equation . Acta Technica Napocensis Appl Math Mech Eng 63(2)

46.

Singh BK, Kumar P (2018) An algorithm based on a new DQM with modified extended cubic B-splines for numerical study of two dimensional hyperbolic telegraph equation. Alex Eng J 57(1):175–191

47.

Singh S, Patel VK, Singh VK, Tohidi E (2018) Application of Bernoulli matrix method for solving two-dimensional hyperbolic telegraph equations with Dirichlet boundary conditions. Comput Math Appl 75(7):2280–2294MathSciNetMATH

48.

Tikhonov A, Samarskii A (1990) Equations of mathematical physics. Dover, New York

49.

Ureña F, Gavete L, Benito J, García A, Vargas A (2020) Solving the telegraph equation in 2-D and 3-D using generalized finite difference method (GFDM). Eng Anal Bound Elem 112:13–24MathSciNetMATH

50.

Wang F, Zhao Q, Chen Z, Fan CM (2021) Localized Chebyshev collocation method for solving elliptic partial differential equations in arbitrary 2D domains. Appl Math Comput 397:125903MathSciNetMATH

51.

Wendland H (1995) Piecewise polynomial, positive definite and compactly supported radial functions of minimal degree. Adv Comput Math 4(1):389–396MathSciNetMATH

52.

Wendland H (2002) Fast evaluation of radial basis functions: Methods based on partition of unity. In: Approximation theory X: wavelets, splines, and applications. Citeseer

53.

Wendland H (2005) Scattered data approximation Cambridge Monographs on Applied and Computational Mathematics, vol 17. Cambridge University Press, Cambridge

54.

Zhao Z, Li H, Liu Y (2020) Analysis of a continuous Galerkin method with mesh modification for two-dimensional telegraph equation. Comput Math Appl 79(3):588–602MathSciNetMATH

Title: An accurate localized meshfree collocation technique for the telegraph equation in propagation of electrical signals
Authors: O. Nikan
Z. Avazzadeh
J. A. Tenreiro Machado
M. N. Rasoulizadeh
Publication date: 08-03-2022
Publisher: Springer London
Published in: Engineering with Computers / Issue 3/2023
Print ISSN: 0177-0667
Electronic ISSN: 1435-5663
DOI: https://doi.org/10.1007/s00366-022-01630-9

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