A Novel Dual Method Approach for Solving Third Order Pseudo Hyperbolic PDEs Using Variational Iteration and Group Preserving Schemes

sadeq abdulazeez

doi:10.5269/bspm.75553

sadeq abdulazeez University of Duhok https://orcid.org/0000-0003-4515-1585

Resumo

The study explores advanced numerical techniques for solving pseudo-hyperbolic equations through an innovative computational approach integrating variational iteration methodology, symmetry-preserving numerical schemes, and a novel fictitious time discretization strategy. By transforming the original mathematical problem into an alternative formulation using fictitious time integration, we develop a robust computational framework that enhances numerical stability and convergence properties. The proposed method leverages group-preserving transformation techniques to maintain critical mathematical symmetries throughout the numerical solution process. Comprehensive numerical experiments are conducted across diverse test scenarios to validate the method's performance and computational efficiency. Rigorous analysis demonstrates the approach's significant advantages, including rapid convergence, high accuracy, and exceptional adaptability to complex pseudo-hyperbolic systems. The research contributes novel insights into advanced computational mathematics, offering a sophisticated alternative to traditional numerical solution strategies for challenging partial differential equations. Detailed numerical simulations substantiate the method's effectiveness, revealing its potential for addressing intricate mathematical modeling challenges in various scientific and engineering domains.

Downloads

Não há dados estatísticos.

Referências

\bibitem{1} Abdulazeez, S.T. and Modanli, M., 2022. Solutions of fractional order pseudo-hyperbolic telegraph partial differential equations using finite difference method. Alexandria Engineering Journal, 61(12), pp.12443-12451.

\bibitem{2} Zhao, Z. and Li, H., 2019. A continuous Galerkin method for pseudo-hyperbolic equations with variable coefficients. Journal of Mathematical Analysis and Applications, 473(2), pp.1053-1072.

\bibitem{3} Modanli, M., Abdulazeez, S.T. and Husien, A.M., 2021. A residual power series method for solving pseudo hyperbolic partial differential equations with nonlocal conditions. Numerical Methods for Partial Differential Equations, 37(3), pp.2235-2243.

\bibitem{4} Mesloub, S., Aboelrish, M.R. and Obaidat, S., 2019. Well posedness and numerical solution for a non-local pseudohyperbolic initial boundary value problem. International Journal of Computer Mathematics, 96(12), pp.2533-2547.

\bibitem{5} Aliev, A.B. and Lichaei, B.H., 2010. Existence and non-existence of global solutions of the Cauchy problem for higher order semilinear pseudo-hyperbolic equations. Nonlinear Analysis: Theory, Methods \& Applications, 72(7-8), pp.3275-3288.

\bibitem{6} Fedotov, I., Shatalov, M. and Marais, J., 2016. Hyperbolic and pseudo-hyperbolic equations in the theory of vibration. Acta Mechanica, 227(11), pp.3315-3324.

\bibitem{7} Sweilam, N.H., Khader, M.M. and Nagy, A.M., 2011. Numerical solution of two-sided space-fractional wave equation using finite difference method. Journal of Computational and Applied Mathematics, 235(8), pp.2832-2841.
\bibitem{8} Yokus, A., Durur, H. and Ahmad, H., 2020. Hyperbolic type solutions for the couple Boiti-Leon-Pempinelli system. Facta Universitatis, Series: Mathematics and Informatics, 35(2), pp.523-531.

\bibitem{9} Liu, C.S., 2001. Cone of non-linear dynamical system and group preserving schemes. International Journal of Non-Linear Mechanics, 36(7), pp.1047-1068.

\bibitem{10} Orumbayeva, N.T., Assanova, A.T. and Keldibekova, A.B., 2022. On an algorithm of finding an approximate solution of a periodic problem for a third-order differential equation. Eurasian Mathematical Journal, 13(1), pp.69-85.

\bibitem{11} Assanova, A.T., 2021. On the solvability of a nonlocal problem for the system of Sobolev-type differential equations with integral condition. Georgian Mathematical Journal, 28(1), pp.49-57.

\bibitem{12} Assanova, A.T. and Kabdrakhova, S.S., 2020. Modification of the Euler polygonal method for solving a semi-periodic boundary value problem for pseudo-parabolic equation of special type. Mediterranean Journal of Mathematics, 17(4), pp.1-30.

\bibitem{13} Tekin, I., Mehraliyev, Y.T. and Ismailov, M.I., 2019. Existence and uniqueness of an inverse problem for nonlinear Klein‐Gordon equation. Mathematical Methods in the Applied Sciences, 42(10), pp.3739-3753.

\bibitem{14} He, J.H., 2007. Variational iteration method—some recent results and new interpretations. Journal of computational and applied mathematics, 207(1), pp.3-17.

\bibitem{15} He, J., 1997. A new approach to nonlinear partial differential equations. Communications in Nonlinear Science and Numerical Simulation, 2(4), pp.230-235.

\bibitem{16} Abbasbandy, S. and Shivanian, E., 2009. Application of the variational iteration method for system of nonlinear Volterra’s integro-differential equations. Mathematical and computational applications, 14(2), pp.147-158.

\bibitem{17} Abdou, M.A. and Soliman, A.A., 2005. Variational iteration method for solving Burger's and coupled Burger's equations. Journal of computational and Applied Mathematics, 181(2), pp.245-251.

\bibitem{18} He, J.H., 2000. Variational iteration method for autonomous ordinary differential systems. Applied mathematics and computation, 114(2-3), pp.115-123.

\bibitem{19} Momani, S. and Abuasad, S., 2006. Application of He’s variational iteration method to Helmholtz equation. Chaos, Solitons \& Fractals, 27(5), pp.1119-1123.

\bibitem{20} Ganji, D.D., Jannatabadi, M. and Mohseni, E., 2007. Application of He's variational iteration method to nonlinear Jaulent–Miodek equations and comparing it with ADM. Journal of Computational and Applied Mathematics, 207(1), pp.35-45.

\bibitem{21} Abdulazeez, S.T., Modanli, M. and Husien, A.M., 2022. NUMERICAL SCHEME METHODS FOR SOLVING NONLINEAR PSEUDO-HYPERBOLIC PARTIAL DIFFERENTIAL EQUATIONS. Journal of Applied Mathematics and Computational Mechanics, 21(4), pp.5-15.

\bibitem{22} Gao, W., Partohaghighi, M., Baskonus, H.M. and Ghavi, S., 2019. Regarding the group preserving scheme and method of line to the numerical simulations of Klein–Gordon model. Results in Physics, 15, p.102555.

\bibitem{23} Partohaghighi, M., Ink, M., Baleanu, D. and Moshoko, S.P., 2019. Ficitious time integration method for solving the time fractional gas dynamics equation. Thermal Science, 23(Suppl. 6), pp.2009-2016.

\bibitem{24} Abbasbandy, S. and Hashemi, M.S., 2011. Group preserving scheme for the Cauchy problem of the Laplace equation. Engineering analysis with boundary elements, 35(8), pp.1003-1009.

\bibitem{25} Chawla, R., Kumar, D. and Singh, S., 2024. A Second-Order Scheme for the Generalized Time-Fractional Burgers' Equation. Journal of Computational and Nonlinear Dynamics, 19(1), p.011001.