×
Ghasemi, M.

Spline-based DQM for multi-dimensional PDEs: application to biharmonic and Poisson equations in 2D and 3D. (English) Zbl 1372.65298

Comput. Math. Appl. 73, No. 7, 1576-1592 (2017).
Summary: The idea of differential quadrature method (DQM) is used to construct a new algorithm for the solution of differential equations. To determine the weighting coefficients of DQM, B-spline basis functions of degree \(r\) are used as test functions. The method is constructed on a set of points mixed from grid points and mid points of a uniform partition. Using the definition of B-splines interpolation as alternative, some error bounds are obtained for DQM. The method is successfully implemented on nonlinear boundary value problems of order \(m\). Also the application of the proposed method to approximate the solution of multi-dimensional elliptic partial differential equations (PDEs) is included in the paper. As test problem, some examples of biharmonic and Poisson equations are solved in 2D and 3D. The results are compared with some existing methods to show the efficiency and performance of the proposed algorithm. Also some examples of time dependent PDEs are solved to compare the results with other existing spline based DQ methods.

Cited in 5 Documents

MSC:

65N22 Numerical solution of discretized equations for boundary value problems involving PDEs
35J05 Laplace operator, Helmholtz equation (reduced wave equation), Poisson equation
35J30 Higher-order elliptic equations
65D07 Numerical computation using splines
35J60 Nonlinear elliptic equations

Keywords:

differential quadrature method; B-spline; multi-dimensional PDEs; Poisson equation; biharmonic equation; numerical example; algorithm; error bound; nonlinear boundary value problems
Cite Review PDF
Full Text: DOI

References:

[1] Timoshenko, S., A Course in the Theory of Elasticity (1972), Naukova Dumka: Naukova Dumka Kiev
[2] Lurie, S.; Vasiliev, V., The Biharmonic Problem of the Theory of Elasticity (1995), Gordon and Breach Publishers: Gordon and Breach Publishers London · Zbl 0924.73007
[3] Timoshenko, S. P., History of Strength of Materials, With a Brief Account of the History of Theory of Elasticity and Theory of Structures (1953), McGraw-Hill: McGraw-Hill New York
[4] Fletcher, C. A.J., Computational Techniques for Fluid Dynamics (1991), Springer: Springer New York · Zbl 0706.76001
[5] Pierce, A. D., Acoustics: An Introduction to Its Physical Principles and Applications (1989), Acoustical Society of America: Acoustical Society of America Woodbury, New York
[6] Harari, I.; Turkel, E., Accurate finite difference methods for time-harmonic wave propagation, J. Comput. Phys., 119, 252-270 (1995) · Zbl 0848.65072
[7] Schumann, U.; Sweet, R. A., Fast Fourier transforms for direct solution of Poissons equation with staggered boundary conditions, J. Comput. Phys., 75, 123-127 (1988) · Zbl 0642.65070
[8] Castillo, J.; Miranda, G., Mimetic Discretization Methods (2013), CRC Press
[9] Shi, Z.; Cao, Y. Y.; Chen, Q. J., Solving 2D and 3D Poisson equations and biharmonic equations by the Haar wavelet method, Appl. Math. Model., 36, 5143-5161 (2012) · Zbl 1254.65138
[10] Shi, Z.; Cao, Y. Y., A spectral collocation method based on Haar wavelets for Poisson equations and biharmonic equations, Appl. Math. Model., 54, 2858-2868 (2011) · Zbl 1235.65160
[11] Gupta, M. M.; Kouatchou, J., Symbolic derivation of finite difference approximations for the three-dimensional Poisson equation, Numer. Methods Partial Differential Equations, 14, 5, 593-606 (1998) · Zbl 0926.65103
[12] Romao, E. C.; Campos, M. D.; Moura, L. F.M., Application of the galerkin and least-squares finite element methods in the solution of 3D Poisson and Helmholtz equations, Comput. Math. Appl., 62, 4288-4299 (2011) · Zbl 1236.65145
[13] Viswanathan, K. K.; Navaneethakrishnan, P. V., Free vibration study of layered cylindrical shells by collocation with splines, J. Sound Vib., 260, 807-827 (2003) · Zbl 1237.74217
[14] Viswanathan, K. K.; Lee, S. K., Free vibration of laminated cross-ply plates including shear deformation by spline method, Int. J. Mech. Sci., 49, 352-363 (2007)
[15] Viswanathan, K. K.; Kim, K. S., Free vibration of antisymmetric angle-ply-laminated plates including transverse shear deformation: Spline method, Int. J. Mech. Sci., 50, 1476-1485 (2008) · Zbl 1264.74105
[16] Viswanathan, K. K.; Kim, K. S.; Lee, J. H.; Koh, H. S.; Lee, J. B., Free vibration of multi-layered circular cylindrical shell with cross-ply walls, including shear deformation by using spline function method, J. Mech. Sci. Tech., 22, 2062-2075 (2008)
[17] Bellman, R.; Kashef, B. G.; Casti, J., Differential quadrature: A technique for the rapid solution of nonlinear partial differential equations, J. Comput. Phys., 10, 40-52 (1972) · Zbl 0247.65061
[18] Civan, F., Differential cubature for multidimensional problems, (Vogt, W. G.; M. H., Mickle, Proc. 20th Ann. Pittsburgh Conf. Model. and Simul. (1989), Instrument Society of American: Instrument Society of American North Carolina), 1843-1847
[20] Shu, C., Generalized differential-integral quadrature and application to the simulation of incompressible viscous flows including parallel computation (1991), Univ of Glasgow: Univ of Glasgow UK, (Ph.D. thesis)
[21] Shu, C.; Chew, YT., Fourier expansion-based differential quadrature and its application to helmholtz eigenvalue problems, Commun. Numer. Methods. Eng., l3, 8, 643-653 (1997) · Zbl 0886.65109
[22] Shu, C.; Xue, H., Explicit computation of weighting coefficients in the harmonic differential quadrature, J. Sound Vib., 204, 3, 549-555 (1997)
[23] Zhong, H., Spline-based differential quadrature for fourth order equations and its application to Kirchhoff plates, Appl. Math. Model., 28, 353-366 (2004) · Zbl 1046.65063
[24] Guo, Q.; Zhong, H., Non-linear vibration analysis of beams by a spline-based differential quadrature method, J. Sound Vib., 269, 413-420 (2004) · Zbl 1236.74294
[25] Zhong, H.; Lan, M., Solution of nonlinear initial-value problems by the spline-based differential quadrature method, J. Sound Vib., 296, 908-918 (2006) · Zbl 1243.65089
[26] Korkmaz, A.; Aksoy, A. M.; Dag, I., Quartic B-spline differential quadrature method, Int. J. Nonlinear Sci., 11, 4, 403-411 (2011)
[27] Arora, G.; Singh, B. K., Numerical solution of Burgers’ equation with modiffied B-spline differential quadrature method, Appl. Math. Comput., 224, 166-177 (2013) · Zbl 1334.65031
[28] Mittal, R. C.; Dahiya, S., Numerical simulation on hyperbolic diffusion equations using modified cubic B-spline differential quadrature methods, Comput. Math. Appl., 70, 5, 737-749 (2015) · Zbl 1443.65277
[29] Mittal and, R. C.; Dahiya, Sumita, Numerical solutions of differential equations using modified b-spline differential quadrature method, (Mathematical Analysis and Its Applications. Mathematical Analysis and Its Applications, Springer Proceedings in Mathematics and Statistics, 143 (2015)), 509-523 · Zbl 1337.65090
[30] Mittal, R. C.; Dahiya, S., A study of quintic b-spline based differential quadrature method for a class of semi-linear Fisher-Kolmogorov equations, Alex. Eng. J., 55, 3, 2893-2899 (2016)
[31] Korkmaz, A.; Dag, I., Cubic B-spline differential quadrature methods for the advection-diffusion equation, Internat. J. Numer. Methods Heat Fluid Flow, 22, 1021-1036 (2012) · Zbl 1357.65216
[32] Korkmaz, A.; Dag, I., Cubic B-spline differential quadrature methods and stability for Burgers equation, Int. J. Comput. Aided Eng. Soft., 30, 3, 320-344 (2013)
[33] Korkmaz, A.; Dag, I., Numerical simulations of boundary-forced RLW equation with cubic B-spline based differential quadrature methods, Arab. J. Sci. Eng., 38, 1151-1160 (2013)
[34] Bashan, A.; Karakoc, B.; Geyikli, T., Approximation of the KdVB equation by the quintic B-spline differential quadrature method, Kuwait J. Sci., 42, 2, 67-92 (2015) · Zbl 1463.65335
[35] Barrera, D.; Gonzalez, P.; Ibnez, F.; Ibnez, M. J., A general spline differential quadrature method based on quasi-interpolation, J. Comput. Appl. Math., 275, 465-479 (2015) · Zbl 1334.65056
[36] Barrera, D.; Gonzalez, P.; Ibnez, F.; Ibnez, M. J., On spline-based differential quadrature, J. Comput. Appl. Math., 275, 272-280 (2015) · Zbl 1334.65032
[37] Tornabene, F.; Fantuzzi, N.; Ubertini, F.; Viola, E., Strong formulation finite element method based on differential quadrature: A survey, Appl. Mech. Rev., 67, 2 (2015), 020801-1-55
[38] Prenter, P. M., Spline and Variational Methods (1975), Wiley: Wiley New York · Zbl 0344.65044
[39] De Boor, C., A Practical Guide to Splines (2001), Springer: Springer New York · Zbl 0987.65015
[40] Shu, C., Differential Quadrature and its Application in Engineering (2000), Athenaeum Press Ltd.: Athenaeum Press Ltd. Great Britain · Zbl 0944.65107
[41] Lucas, T. R., Asymptotic expansions for interpolating periodic splines, SIAM J.Numer. Anal., 19, 5, 1051-1066 (1982) · Zbl 0519.41010
[42] Meek, D., Some new linear relations for even degree polynomial splines on a uniform mesh, BIT, 20, 382-384 (1980) · Zbl 0454.65011
[43] Dubeau, F.; Savoie, J., Periodic even degree spline interpolation on a uniform partition, J. Approx. Theory, 4, 43-54 (1985) · Zbl 0622.41002
[44] Christara, C. C., Quadratic spline collocation methods for elliptic partial differential equations, BIT, 34, 33-61 (1994) · Zbl 0815.65118
[45] EL-Gamel, M.; El-Shenawy, A., The solution of a time dependent problemby the B-spline method, Appl. Math. Comput., 267, 254-265 (2014) · Zbl 1293.65132
[46] Mohanty, R., An unconditionally stable difference scheme for the one space dimensional linear hyperbolic equation, Appl. Math. Lett., 17, 101-105 (2004) · Zbl 1046.65076
This reference list is based on information provided by the publisher or from digital mathematics libraries. Its items are heuristically matched to zbMATH identifiers and may contain data conversion errors. In some cases that data have been complemented/enhanced by data from zbMATH Open. This attempts to reflect the references listed in the original paper as accurately as possible without claiming completeness or a perfect matching.