Modal spectral Tchebyshev Petrov–Galerkin stratagem for the time-fractional nonlinear Burgers’ equation

Document Type : Research Article

Authors

1 Department of Mathematics, Faculty of Science, Cairo University, Giza 12613, Egypt.

2 Department of Mathematics, Faculty of Education, Ain Shams University, Roxy, Cairo 11341, Egypt.

Abstract

Herein, we construct an explicit modal numerical solver based on the spec-tral Petrov–Galerkin method via a specific combination of shifted Cheby-shev polynomial basis for handling the nonlinear time-fractional Burger-type partial differential equation in the Caputo sense. The process reduces the problem to a nonlinear system of algebraic equations. Solving this alge-braic equation system will yield the approximate solution’s unknown coef-ficients. Many relevant properties of Chebyshev polynomials are reported, some connection and linearization formulas are reported and proved, and all elements of the obtained matrices are evaluated neatly. Also, conver-gence and error analyses are established. Various illustrative examples demonstrate the applicability and accuracy of the proposed method and depict the absolute and estimated error figures. Besides, the current ap-proach’s high efficiency is proved by comparing it with other techniques in the literature.

Keywords

Main Subjects

References

[1] Abd-Elhameed, W.M., Machado, J.A.T. and Youssri, Y.H. Hypergeo-metric fractional derivatives formula of shifted Chebyshev polynomials: tau algorithm for a type of fractional delay differential equations, Int. J. Nonlinear Sci. Numer. 23(7-8) (2022), 1253–1268.
[2] Abd-Elhameed, W.M., Doha, E.H., Youssri, Y.H. and Bassuony, M.A. New TChebyshev-Galerkin operational matrix method for solving lin-ear and nonlinear hyperbolic telegraph type equations, Numer. Methods Partial Differ. Equ. 32(6) (2016), 1553–1571.
[3] Abd-Elhameed, W.M., Youssri, Y.H., Amin, A.K. and Atta, A.G. Eighth-kind Chebyshev polynomials collocation algorithm for the nonlin-ear time-fractional generalized Kawahara equation, Fractal Fract. 7(9) (2023), 652.
[4] Askey, R. Orthogonal polynomials and special functions, Society for In-dustrial and Applied Mathematics, Philadelphia, PA, 1975.
[5] Atangana, A. and Owolabi, K.M. New numerical approach for fractional differential equations, Math. Model. Nat. Phenom. 13(1) (2018), 3.
[6] Atta, A.G., Abd-Elhameed, W.M. and Youssri, Y.H. Shifted fifth-kind Chebyshev polynomials Galerkin-based procedure for treating fractional diffusion-wave equation, Int. J. Mod. Phys. C. 33(08) (2022), 2250102.
[7] Atta, A.G., Abd-Elhameed, W.M., Moatimid, G.M. and Youssri, Y.H. Shifted fifth-kind Chebyshev Galerkin treatment for linear hyperbolic first-order partial differential equations, Appl. Numer. Math. 167 (2021), 237–256.
[8] Atta, A.G., Abd-Elhameed, W.M., Moatimid, G.M. and Youssri, Y.H. Advanced shifted sixth-kind Chebyshev tau approach for solving linear one-dimensional hyperbolic telegraph type problem, Math. Sci. (2022), 1–15.
[9] Atta, A.G., Abd-Elhameed, W.M., Moatimid, G.M. and Youssri, Y.H. A fast Galerkin approach for solving the fractional Rayleigh–Stokes problem via sixth-kind Chebyshev polynomials, Mathematics 10(11) (2022), 1843.
[10] Atta, A.G., Abd-Elhameed, W.M., Moatimid, G.M. and Youssri, Y.H. Novel spectral schemes to fractional problems with nonsmooth solutions, Math. Methods Appl. Sci. 46(13) (2023), 14745–14764.
[11] Bernardi, C. and Maday, Y. Spectral methods, Handbook of numeri-cal analysis, Vol. V, 209–485, Handb. Numer. Anal., V, North-Holland, Amsterdam, 1997.
[12] Bhrawy, A.H. and Zaky, M.A. A method based on the Jacobi tau approx-imation for solving multi-term time–space fractional partial differential equations, J. Comput. Phys. 281 (2015), 876–895.
[13] Boyd, J.P. Chebyshev and Fourier spectral methods, Chebyshev and Fourier spectral methods. Second edition. Dover Publications, Inc., Mi-neola, NY, 2001.
[14] Canuto, C., Hussaini, M.Y., Quarteroni, A. and Zang, T.A. Spectral methods: fundamentals in single domains, Springer Science & Business Media, 2007.
[15] Chawla, R., Deswal, K.,Kumar, D. and Baleanu, D. Numerical simula-tion for generalized time-fractional Burgers’ equation with three distinct linearization schemes, J. Comput. Nonlinear Dyn. 18(4) (2023), 041001.
[16] Costabile, F. and Napoli, A. A class of collocation methods for numerical integration of initial value problems, Computers & Mathematics with Applications 62(8) (2011), 3221–3235.
[17] Doha, E.H., Abd-Elhameed, W.M., Elkot, N.A. and Youssri, Y.H. Inte-gral spectral TChebyshev approach for solving space Riemann-Liouville and Riesz fractional advection-dispersion problems, Advances in Differ-ence Equations 2017(1) (2017), 1–23.
[18] Doley, S., Kumar, A.V., Singh, K.R. and Jino, L. Study of Time Frac-tional Burgers’ Equation using Caputo, Caputo-Fabrizio and Atangana-Baleanu Fractional Derivatives, Engineering Letters 30(3) (2022).
[19] Gottlieb, D. and Orszag, S.A. Numerical analysis of spectral methods: theory and applications, CBMS-NSF Regional Conference Series in Ap-plied Mathematics, No. 26. Society for Industrial and Applied Mathe-matics, Philadelphia, PA, 1977.
[20] Guo, B. Spectral methods and their applications, World Scientific Pub-lishing Co., Inc., River Edge, NJ, 1998.
[21] Karaagac, B. and Owolabi, K.M. Numerical analysis of polio model: A mathematical approach to epidemiological model using derivative with Mittag–Leffler Kernel, Math. Methods Appl. Sci. 46(7) (2023), 8175–8192.
[22] Karaagac, B., Owolabi, K.M. and Pindza, E. A computational technique for the Caputo fractal-fractional diabetes mellitus model without genetic factors, International Journal of Dynamics and Control (2023), 1–18.
[23] Karaagac, B., Esen, A., Owolabi, K.M. and Pindza, E. A collocation method for solving time fractional nonlinear Korteweg–de Vries–Burgers equation arising in shallow water waves, Int. J. Mod. Phys. C. 34(07) (2023), 2350096.
[24] Korkmaz, E. and Yildirim, K. A meshfree time-splitting approach for the time-fractional Burgers’ equation, Journal of Mathematics (2023), 2023.
[25] Magdy, E., Abd-Elhameed, W.M., Youssri, Y.H., Moatimid, G.M. and Atta, A.G. A potent collocation approach based on shifted gegenbauer polynomials for nonlinear time fractional Burgers’ equations, Contemp. Math. 4(2) (2023), 647–665.
[26] Moghaddam, B.P., Dabiri, A., Lopes, A.M. and Machado, J.A.T. Nu-merical solution of mixed-type fractional functional differential equations using modified Lucas polynomials, Comput. Appl. Math. 38 (2019), 1–12.
[27] Moustafa, M., Youssri, Y.H. and Atta, A.G. Explicit Chebyshev Petrov–Galerkin scheme for time-fractional fourth-order uniform Euler–Bernoulli pinned–pinned beam equation, Nonlinear Eng. 12(1) (2023), 20220308.
[28] Najafi, M., Arefmanesh, A. and Enjilela, V. Meshless local Petrov–Galerkin method-higher Reynolds numbers fluid flow applications, Eng. Anal. Bound. Elem. 36(11) (2012), 1671–1685.
[29] Owolabi, K.M. Numerical approach to chaotic pattern formation in dif-fusive predator–prey system with Caputo fractional operator, Numer. Methods Partial Differ. Equ. 37(1) (2021), 131–151.
[30] Owolabi, K.M. Analysis and numerical simulation of cross reaction–diffusion systems with the Caputo–Fabrizio and Riesz operators, Numer. Methods Partial Differ. Equ. 39(3) (2023), 1915–1937.
[31] Peng, X., Xu, D. and Qiu, W. Pointwise error estimates of compact dif-ference scheme for mixed-type time-fractional Burgers’ equation, Math. Comput. Simul. 208 (2023), 702–726.
[32] Podlubny, I. Fractional differential equations: An introduction to frac-tional derivatives, fractional differential equations, to methods of their solution and some of their applications, Elsevier, 1998.
[33] Shafiq, M., Abbas, M., Abdullah, F.A., Majeed, A., Abdeljawad, T. and Alqudah, M.A. Numerical solutions of time fractional Burgers’ equation involving Atangana–Baleanu derivative via cubic B-spline functions, Re-sults Phys. 34 (2022), 105244.
[34] Shen, J. A new dual-Petrov–Galerkin method for third and higher odd-order differential equations: application to the KdV equation, SIAM J. Numer. Anal. 41(5) (2003), 1595–1619.
[35] Trefethen, L.N. Spectral methods in MATLAB, Software, Environments, and Tools, 10. Society for Industrial and Applied Mathematics (SIAM), Philadelphia, PA, 2000.
[36] Wang, H., Sun, Y., Qian, X. and Song, S. A high-order compact dif-ference scheme on graded mesh for time-fractional Burgers’ equation, Comput. Appl. Math. 42(1) (2023), 18.
[37] Yadav, S. and Pandey, R.K. Numerical approximation of fractional Burg-ers equation with Atangana–Baleanu derivative in Caputo sense, Chaos Solitons Fractals 133 (2020), 109630.
[38] Youssri, Y.H. and Atta, A.G. Double TChebyshev spectral tau algorithm for solving KdV equation, with soliton application, Solitons, New York, NY: Springer US, 2022, 451–467.
[39] Youssri , Y.H. and Atta, A.G. Petrov-Galerkin Lucas polynomials proce-dure for the time-fractional diffusion equation, Contemp. Math. (2023), 230–248.
[40] Youssri, Y.H. and Atta, A.G. Spectral collocation approach via normal-ized shifted Jacobi polynomials for the nonlinear Lane-Emden equation with fractal-fractional derivative, Fractal Fract. 7(2) (2023), 133.
[41] Youssri, Y.H. and Muttardi, M.M. A mingled tau-finite difference method for stochastic first-order partial differential equations, Int. J. Appl. Com-put. Math. 9(2) (2023), 14.
[42] Youssri, Y.H., Abd-Elhameed, W.M. and Abdelhakem, M. A robust spec-tral treatment of a class of initial value problems using modified Cheby-shev polynomials, Math. Methods Appl. Sci. 44(11) (2021), 9224–9236.
[43] Yuan, J., Shen, J. and Wu, J. A dual-Petrov-Galerkin method for the Kawahara-type equations, J. Sci. Comput. 34(1) (2008), 48–63.
[44] Zhang, Y. and Feng, M. A local projection stabilization virtual element method for the time-fractional Burgers equation with high Reynolds num-bers, Appl. Math. Comput. 436 (2023), 127509.
Send comment about this article
CAPTCHA Image

Files

Share

How to cite

Statistics