A semi-analytic and numerical approach to the fractional differential equations

Document Type : Research Article

Authors

Department of Mathematics, Bangalore University, Bengaluru-560056, India.

10.22067/ijnao.2024.85120.1331

Abstract

A class of linear and nonlinear fractional differential equations (FDEs) in the Caputo sense is considered and studied through two novel techniques called the Homotopy analysis method (HAM). A reliable approach is proposed for solving fractional order nonlinear ordinary differential equations, and the Haar wavelet technique (HWT) is a numerical approach for both integer and noninteger orders. Perturbation techniques are widely applied to gain analytic approximations of nonlinear equations. However, perturbation methods are essentially based on small physical parameters (called perturbation quantity), but unfortunately, many nonlinear problems have no such kind of small physical parameters at all. HAM overcomes this, and HWT does not require any parameters. Due to this, we opt for HAM and HWT to study FDEs. We have drawn a semi-analytical solution in terms of a series of polynomials and numerical solutions for FDEs. First, we solve the models by HAM by choosing the preferred control parameter. Second, HWT is considered. Through this technique, the operational matrix of integration is used to convert the given FDEs into a set of algebraic equation systems. Four problems are discussed using both techniques. Obtained results are expressed in graphs and tables. Results on convergence have been discussed in terms of theorems.  

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References

[1] Adomian, G. Solving frontier problems of physics: the decomposition method, Springer, Dordrecht, 1994.
[2] Ahmed, H.F., Bahgat, M.S. and Zaki, M., Numerical approaches to system of fractional partial differential equations, J. Egypt. Math. Soc. 25(2) (2017), 141–150.
[3] Balaji, S. Legendre wavelet operational matrix method for solution of fractional order Riccati differential equation, J. Egypt. Math. Soc. 23(2) (2015), 263–270.
[4] Cabada, A. and Wang, G. Positive solutions of nonlinear fractional differential equations with integral boundary value conditions, J. Math. Anal. Appl. 389(1) (2012), 403–411.
[5] Chauhan, J.P. and Khirsariya, S.R. A semi-analytic method to solve nonlinear differential equations with arbitrary order, Results Control Optim. 12 (2023), 100267.
[6] Chen, Y., Yi, M. and Yu, C. Error analysis for numerical solution of fractional differential equation by Haar wavelets method, J. Comput. Sci. 3(5) (2012), 367–373.
[7] El-Ajou, A., Odibat, Z., Momani, S. and Alawneh, A. construction of analytical solutions to fractional differential equations using homotopy analysis method, IAENG Int. J. Appl. Math. 40(2) (2010).
[8] Kanth, A.R. and Aruna, K. Solution of fractional third-order dispersive partial differential equations, Egypt. J. Basic Appl. Sci. 2(3) (2015), 190–199. 
[9] Khirsariya, S.R. and Rao, S.B. On the semi-analytic technique to deal with nonlinear fractional differential equations, J. Appl. Math. Comput. Mech. 22(1) (2023).
[10] Khirsariya, S.R. and Rao, S.B. Solution of fractional Sawada–Kotera–Ito equation using Caputo and Atangana–Baleanu derivatives, Math. Methods Appl. Scie. 46(15) (2023), 16072–16091.
[11] Khirsariya, S., Rao, S. and Chauhan, J. Semi-analytic solution of timefractional Korteweg-de Vries equation using fractional residual power series method, Results Nonlinear Anal. 5(3) (2022), 222–234.
[12] Khirsariya, S.R., Rao, S.B. and Hathiwala, G.S. Investigation of fractional diabetes model involving glucose–insulin alliance scheme, Int. J. Dyn. Contr. 12(1) (2024), 1–14.
[13] Kumbinarasaiah, S. A novel approach for multi dimensional fractional coupled Navier–Stokes equation, SeMA J. 80(2) (2023), 261–282.
[14] Kumbinarasaiah, S. and Mulimani, M. The Fibonacci wavelets approach for the fractional Rosenau–Hyman equations, Results Control Optim. 11 (2023), 100221.
[15] Kumbinarasaiah, S. and Mundewadi, R.A. Numerical solution of fractional-order integro-differential equations using Laguerre wavelet method, J. Inform. Optim. Scie. 43(4) (2022), 643–662.
[16] Kumbinarasaiah, S. and Preetham, M.P. A study on homotopy analysis method and clique polynomial method, Comput. Methods Differ. Equ. 10(3) (2022), 774–788.
[17] Lazarević, M.P. and Spasić, A.M. Finite-time stability analysis of fractional order time-delay systems: Gronwall’s approach, Math. Comput. Model. 49(3-4) (2009), 475–481.
[18] Liang, S. and Jeffrey, D.J. Comparison of homotopy analysis method and homotopy perturbation method through an evolution equation, Commun. Nonlinear Sci. Numer. Simul. 14(12) (2009), 4057–4064.
[19] Liao, S. An explicit, totally analytical approximate solution for Blasius equation [J], Int. J. Non-Linear Mech. 34 (1999), 759–778.
[20] Liao, S.J. The proposed homotopy analysis technique for the solution of nonlinear problems, Diss. PhD thesis, Shanghai Jiao Tong University, 1992.
[21] Liao, S. Beyond perturbation: introduction to the homotopy analysis method, CRC press, 2003.
[22] Liao, S. Homotopy analysis method in nonlinear differential equations, Beijing: Higher education press, 2012.
[23] Liao, S. ed. Advances in the homotopy analysis method, World Scientific, 2013.
[24] Lin, R. and Liu, F. Fractional high order methods for the nonlinear fractional ordinary differential equation, Nonlinear Anal. Theory Methods Appl. 66(4) (2007), 856–869.
[25] Motsa, S.S., Sibanda, P., Awad, F.G. and Shateyi, S. A new spectralhomotopy analysis method for the MHD Jeffery–Hamel problem, Comput. Fluids 39(7) (2010) , 1219–1225.
[26] Odibat, Z.M. A study on the convergence of homotopy analysis method, Appl. Math. Comput. 217(2) (2010), 782–789.
[27] Podlubny, I. Fractional differential equations: an introduction to fractional derivatives, fractional differential equations, to methods of their solution and some of their applications, Elsevier, 1998.
[28] Prakash, A., Veeresha, P., Prakasha, D.G. and Goyal, M. A homotopy technique for a fractional order multi-dimensional telegraph equation via the Laplace transform, Eur. Phys. J. Plus 134 (2019), 1–18.
[29] Rahimy, M. Applications of fractional differential equations, Appl. Math. Sci 4(50) (2010), 2453–2461.
[30] Sajid, M. and Hayat, T. Comparison of HAM and HPM methods in nonlinear heat conduction and convection equations, Nonlinear Anal. Real World Appl. 9(5) (2008), 2296–2301.
[31] Semary, M.S. and Hany, N.H. The homotopy analysis method for strongly nonlinear initial/boundary value problems, Int. J. Modern Math. Sci. 9(3) (2014), 154–172.
[32] Shawagfeh, N.T. Analytical approximate solutions for nonlinear fractional differential equations, Appl. Math. Comput. 131 (2-3) (2002), 517–529.
[33] Shiralasetti, S. Some results on Haar wavelets matrix through linear algebra, Wavelet and Linear Algebra 4(2) (2017), 49–59. 
[34] Srinivasa, K. and Rezazadeh, H. Numerical solution for the fractionalorder one-dimensional telegraph equation via wavelet technique, Int. J. Nonlinear Sci. Numer. Simul. 22(6) (2021), 767–780.
[35] Srivastava, V.K., Awasthi, M.K. and Kumar, S. Analytical approximations of two and three dimensional time-fractional telegraphic equation by reduced differential transform method, Egypt. J. Basic Appl. Sci. 1(1) (2014), 60–66.
[36] Srinivasa, K., Baskonus, H.M. and Guerrero Sánchez, Y. Numerical solutions of the mathematical models on the digestive system and covid-19 pandemic by hermite wavelet technique, Symmetry 13 (12) (2021), 2428.
[37] Srivastava, V.K., Kumar, S., Awasthi, M.K. and Singh, B.K. Twodimensional time fractional-order biological population model and its analytical solution, Egypt. J. Basic Appl. Sci. 1(1) (2014), 71–76.
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