konuralp j. math. Konuralp Journal of Mathematics 2147-625X Mehmet Zeki SARIKAYA Applied Mathematics (Other) Uygulamalı Matematik (Diğer) More Accurate Solutions for Approximate Solutions of the Benjamin Bona Mahony Equation with A New Technique https://orcid.org/0000-0003-3412-4370 Karta Melike 04 30 2026 14 1 70 86 01 06 2026 03 10 2026 Copyright © 2013, Konuralp Journal of Mathematics 2013 Konuralp Journal of Mathematics

In the field of mathematical modeling, numerical calculations for natural systems and obtaining travelling wave solutions of nonlinear wave equations in relation to sciences like optics, fluid mechanics, solid state physics, plasma physics, kinetics, and geology have recently gained significant importance. Numerous approaches have been proposed for this. The method used in this article is to get more accurate numerical solutions for the Benjamin Bona Mahony (BBM) equation, one of the equations used to simulate the aforementioned nonlinear phenomena. This is accomplished by applying the Lie-Trotter splitting technique to the BBM equation. First, the problem is divided into two subproblems with derivatives with respect to time, one of which is linear and the other of which is nonlinear. Secondly, the galerkin finite element method (FEM) based on the cubic B-spline approximate functions for spatial discretization and the practical classical finite difference approaches for temporal discretization is used to reduce each subproblem to the algebraic equation system. The Lie Trotter splitting algorithm is then used to solve the obtained systems. Explanatory test problems are taken into consideration, demonstrating the newly suggested algorithm's superior accuracy over earlier approaches. Tables and graphs display the numerical results generated by the suggested algorithm. The new approach's stability analysis is also looked at. In light of the outcomes and the price of Matlab computation software, it is appropriate to say that this new method can be applied with ease to partial differential equations used in other fields.

 Cubic B-splines Galerkin method BBM equation Lie Trotter splitting [1] G. Arora, R.C. Mittal , B.K. Singh, Numerical solution of BBM-Burger equation with quartic B-Spline collocation Method, Journal of Engineering Science and Technology Special issue on ICMTEA 2013 Conference; 2014 104–116. [2] B. Saka, ˙I. Da˘g, D.Irk, Quintic B-spline collocation method for numerical solution of the RLW equation, ANZIAM J., 49(2008), 389–410. [3] A. Bas¸han . A novel outlook to the an alternative equation for modelling shallow water wave: Regularised Long Wave (RLW) equation, Indian J Pure Appl. Math; 54 (2023), 133–145. [4] F. Bulut, O¨ . Oruc¸, A. Esen, Higher order Haar wavelet method integrated with strang splitting for solving regularized long wave equation, Mathematics and Computers in Simulation; 197 (2022), 277-290. [5] B. Saka, A. Sahin, ˙I. Da˘g; B-Spline Collocation Algorithms for Numerical Solution of the RLW Equation, Numerical Methods for Partial Differential Equations, 2009, DOI 10.1002/num. [6] N.G. Chegini, A. Salaripanah, R. Mokhtari, D.Isvand, Numerical solution of the regularized long wave equation using nonpolynomial splines, Nonlinear Dyn., 69 (2012) 459–471. DOI 10.1007/s11071-011-0277-y [7] I˙. Dag˘, M.N. O¨ zer, Approximation of RLW equation by least square cubic B-spline finite element method. Applied Mathematical Modelling., 25 (2001) 221–231. [8] ˙I.Da˘g, A. Do˘gan, B. Saka; B-spline collocation methods for numerical solutions of the RLW equation, Intern. J. Computer Math., 80 (2003), 743–757. [9] A. Dogan, Numerical solution of RLW equation using linear finite elements within Galerkin’s method, Applied Mathematical Modelling; 26 (2002), 771–783. [10] D. Abdulkadir, Numerical solution of regularized long wave equation using Petrov–Galerkin method, Commun. Numer. Meth. Engn; 17 (2001), 485–494. DOI: 10.1002/cnm.424. [11] D. Kaya, Salah M.El-Sayed, An application of the decomposition method for the generalized KdV and RLW equations, Chaos, Solitons and Fractals; 17 (2003), 869–877. [12] Esen A, Kutluay S. Application of a lumped Galerkin method to the regularized long wave equation, Applied Mathematics and Computation; 174 (2006), 833–845. [13] L.R.T, Gardner, G.A, Gardner, ˙I.Da˘g, A B-spline finite element method for the regularized long wave equation, Communications in Numerical Methods in Engineering; 11 (1995), 59–68. [14] L.R.T, Gardner, G.A, Gardner, A. Dogan, A least-squares finite element scheme for the RLW equation, Communications in Numerical Methods in Engineering; 12 (1996), 795–804. [15] ˙I. Da˘g, D. Yılmaz, Numerical solution of RLW equation using radial basis functions international Journal of Computer Mathematics; 87 (1), 2010, 63–76. [16] M. Karta, Numerical solution for Benjamin-Bona-Mahony-Burgers equation with Strang time-splitting technique. Turkish Journal of Mathematics; 47 (2023), 537 – 553. [17] M. Karta, More Efficient Solutions for Numerical Analysis of the Nonlinear Generalized Regularized Long Wave (Grlw) Using the Operator Splitting Method, Fundamental Journal of Mathematics and Applications, 8(2) (2025), 72-87. [18] M. Karta, Numerical approach of fisher’s equation with strang splitting technique using finite element Galerkin method, Sigma J. Eng. Nat.Sci; Vol. 41 (2),2023, 344-355. [19] A. Bas¸han, N.M. Ya˘gmurlu, A mixed method approach to the solitary wave, undular bore and boundary-forced solutions of the Regularized Long Wave equation, Computational and Applied Mathematics; 41 (169), 2022, 1-20. https://doi.org/10.1007/s40314-022-01882-7. [20] A. Bas¸han, Single Solitary Wave and Wave Generation Solutions of the Regularised Long Wave (RLW) Equation, Gazi University Journal of Science; 5 (4), 2022, 1597 - 1612. [21] A. Bas¸han, Modification of quintic B-spline differential quadrature method to nonlinear Korteweg-de Vries equation and numerical experiments, Applied Numerical Mathematics; 167 (2021) 356–374. [22] A. Bas¸han, N.M. Ya˘gmurlu, Y.Uc¸ar, A.Esen, A new perspective for the numerical solution of the Modified Equal Width wave equation, Mathematical Methods in Applied sciences; 44 (11), 2021, 8925-8939. [23] S.B.G. Karakoc¸, S.K. Bhowmik, Galerkin finite element solution for Benjamin– Bona–Mahony–Burgers equation with cubic B-splines, Computers and Mathematics with Applications; 77 (2019), 1917–1932. [24] S. Kutluay, A. Esen, A finite difference solution of the regularized long wave equation, Mathematical Problems in Engineering; 2006; 1-14. DOI: 10.1155/MPE/2006/85743. [25] S. Kutluay, M. Karta, Y. Uc¸ar, Strang time-splitting technique for the generalised Rosenau–RLW equation, Pramana Journal of Physics; 95 (2021) 148. https://doi.org/ 10.1007/s12043-021-02182-1. [26] K. L. Redouane, N. Arar, A.Ben Makhlouf, A. Alhashash, Higher-Order Improved Runge–Kutta Method and Cubic B-Spline Approximation for the One-Dimensional Nonlinear RLW Equation, Mathematical Problems in Engineering; 13,2023. [27] L. Mei, Y. Chen, Numerical solutions of RLW equation using Galerkin method with extrapolation techniques, Computer Physics Communications; 183 (2012), 1609–1616. [28] A. Mohebbi, Z.Faraz, Solitary wave solution of nonlinear Benjamin–Bona–Mahony–Burgers equation using a high-order difference scheme, Computational and Applied Mathematics; 36 (2017), 915–927. [29] K.Omrani, M. Ayadi, Finite difference discretization of the Benjamin-Bona-Mahony-Burgers equation, Numerical Methods for Partial Differential Equations; 24(1), 2007, 239–248. [30] O. Oruc, F. Bulut and A. Esen Numerical Solutions of Regularized Long Wave Equation By Haar Wavelet Method, Mediterr. J. Math., 13 (2016), 3235–3253, DOI 10.1007/s00009-016-0682-z. [31] O¨ . Oruc¸, A. Esen, F. Bulut, A strang splitting approach combined with Chebyshev wavelets to solve the regularized long-wave equation numerically, Mediterranean Journal of Mathematics; 17(5), 2020, 1-18. [32] D. H. Peregrine, Calculations of the development of an undular bore. Journal of Fluid Mechanics 25 (2), 1996, 321–330. [34] M.A. Raupp, Galerkin Methods Applied to the Benjamin-Bona-Mahony Equation. Boletim da Sociedade Brasileira de Matem´atica; 6 (1975), 65-77. [35] B. Saka, ˙I. Da˘g, A. Do˘gan, Galerkin method for the Numerical Solution of the RLW Equation using Quadratic B- Spline, International Journal of Computer Mathematics; 81 (6), 2004, 727–739. [36] I. Siraj-ul, H. Sirajul, A. Arshed, Method for the numerical solution of the RLW equation, Journal of Computational and Applied Mathematics; 223 (2009), 997–1012. [37] S.T. Ejaz, SA Qamar, A. Akg¨ul, MK. Hassani, Subdivision collocation method for numerical treatment of regularized long wave (RLW) equation, AIP Advances; 14 (2024). https://doi.org/10.1063/5.0185145 [38] B. Saka, ˙I. Da˘g , A numerical solution of the RLW equation by Galerkin method using quartic B-splines, Commun. Numer. Meth. Engn; 24 (2008), 1339–1361. [39] S. Kutluay, N.M. Ya˘gmurlu,A.S. Karakas¸, s A robust septic hermite collocation technique for dirichlet boundary condition Heat conduction equation, International Journal of Mathematics and Computer in Engineering; 3(2), 2025, 253–266. [40] A novel perspective for simulations of the Modified Equal-Width Wave equation by cubic Hermite B-spline collocation method, Wave Motion 129 (2024) 103342 [41] A.A, Soliman, M.H. Hussien, Collocation solution for RLW equation with septic spline, Applied Mathematics and Computation, 161 2005, 623–636. [42] A.A, Soliman, K.R. Raslan, Collocation method using quadratic B-spline for the RLW equation, International Journal of Computer Mathematics; 78 (2001), 399–412. [43] B. Sportisse, An analysis of operator splitting techniques in the stiff case, Journal of Computational Physics; 161 (2000), 140–168. [44] J.I. Ramos Explicit finite difference methods for the EW and RLW equations, Applied Mathematics and Computation; 179 (2006), 622–638. [45] N.M. Yagmurlu, Y. Ucar, ˙I. Celikkaya, Operator Splitting For Numerical Solutions Of The RLWEquation, Journal of Applied Analysis and Computation; 8(5), 2018, 1494-1510. http://jaac-online.com/DOI:10.11948/2018 [46] Y. Liu, H. Li, Y. Du, J Wang, Explicit Multistep Mixed Finite Element Method for RLW Equation, Abstract and Applied Analysis; 12, 2013, Article ID 768976. [47] M. Zarebnia, R. Parvaz, Cubic B-spline collocation method for numerical solution of the Benjamin-Bona-Mahony-Burgers equation, International Journal of Mathematics and Computer Science; 7(3), 2013 540–543. [48] M. Zarebnia, R. Parvaz, On the numerical treatment and analysis of Benjamin –Bona –Mahony –Burgers equation, Applied Mathematics and Computation; 284 (2016), 79–88. [49] M. Zarebnia, R. Parvaz, Numerical study of the Benjamin-Bona-Mahony-Burgers equation, Boletim da Sociedade Paranaense de Matematica; 35(1), 2017, 127–138. [50] M. Zarebnia, R. Parvaz, Error Analysis of the Numerical Solution of the Benjamin- Bona-Mahony-Burgers Equation, Boletim da Sociedade Paranaense de Matematica; 38(3), 2020, 177–191. Doi: 10.5269/bspm. v38i3.34498. [51] A. Zaki, Solitary waves of the splitted RLW equation. Comput. Phys. Com mun., 138 (2001), 80–91 R. Zhong, X. Wang, Y. He, Numerical analysis of two new three-point conservative compact difference schemes based on reduction method for solving RLW equation, Journal of Dıfference Equatıons and Applıcatıons; 1 (4), 2025, 588–617. https://doi.org/10.1080/10236198.2024.2444929.