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International Journal of Computer Mathematics Volume 101, 2024 - Issue 2
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Research Article

An optimization method for solving a general class of the inverse system of nonlinear fractional order PDEs

Z. Avazzadeha Department of Mathematical Sciences, University of South Africa, Pretoria, South Africa
,
H. Hassanib Department of Mathematics, Anand International College of Engineering, Jaipur, IndiaCorrespondence[email protected] [email protected]
,
M. J. Ebadic Department of Mathematics, Chabahar Maritime University, Chabahar, Iran;f Section of Mathematics, International Telematic University Uninettuno, Corso Vittorio Emanuele II, 39, 00186 Roma, ItalyCorrespondence[email protected]
,
A. Bayati Eshkaftakid Faculty of Mathematics, Shahrekord University, Shahrekord, Iran
&
A. S. Hendye Department of Mathematics, Faculty of Science, Benha University, Benha, Egypt
Pages 138-153 | Received 15 Aug 2023, Accepted 03 Feb 2024, Published online: 13 Feb 2024

References

  • Z. Abdollahi, M. Mohseni Moghadam, H. Saeedi, and M.J. Ebadi, A computational approach for solving fractional Volterra integral equations based on two-dimensional Haar wavelet method, Int. J. Comput. Math. 99(7) (2022), pp. 1488–1504.
  • P. Alipour, The BEM and DRBEM schemes for the numerical solution of the two-dimensional time-fractional diffusion-wave equations, preprint (2023). Available at arXiv:2305.12117.
  • Z. Avazzadeh, H. Hassani, P. Agarwal, S. Mehrabi, M.J. Ebadi, and M.S. Dahaghin, An optimization method for studying fractional-order tuberculosis disease model via generalized Laguerre polynomials, Soft Comput. 27(14) (2023), pp. 9519–9531.
  • Z. Avazzadeh, H. Hassani, P. Agarwal, S. Mehrabi, M. Javad Ebadi, and M.K. Hosseini Asl, Optimal study on fractional fascioliasis disease model based on generalized Fibonacci polynomials, Math. Methods Appl. Sci. 46 (2023), pp. 9332–9350.
  • Z. Avazzadeh, H. Hassani, M.J. Ebadi, P. Agarwal, M. Poursadeghfard, and E. Naraghirad, Optimal approximation of fractional order brain tumor model using generalized Laguerre polynomials, Iranian Journal of Science 47 (2023), pp. 501–513.
  • Z. Avazzadeh, H. Hassani, A.B. Eshkaftaki, M.J. Ebadi, M.K. Hosseini Asl, P. Agarwal, S. Mehrabi, and M.S. Dahaghin, An efficient algorithm for solving the fractional hepatitis B treatment model using generalized bessel polynomial, Iran. J. Sci. 47 (2023), pp. 1649–1664.
  • A. Babaei and S. Banihashemi, Reconstructing unknown nonlinear boundary conditions in a time-fractional inverse reaction-diffusion-convection problem, Numer Methods. Partial. Differ. Equ. 35(3) (2019), pp. 976–992.
  • A. Bhrawy and M. Zaky, A fractional-order Jacobi Tau method for a class of time-fractional PDEs with variable coefficients, Math. Methods. Appl. Sci. 39(7) (2016), pp. 1765–1779.
  • Y. Chen, Y. Sun, and L. Liu, Numerical solution of fractional partial differential equations with variable coefficients using generalized fractional-order Legendre functions, Appl Math. Comput. 244 (2014), pp. 847–858.
  • R. Choupanzadeh and A. Zadehgol, Stability, causality, and passivity analysis of canonical equivalent circuits of improper rational transfer functions with real poles and residues, IEEE Access 8 (2020), pp. 125149–125162.
  • M.S. Dahaghin and H. Hassani, A new optimization method for a class of time fractional convection-diffusion-wave equations with variable coefficients, Eur. Phys. J. Plus. 132 (2017), p. 130.
  • M. Erfanian, H. Zeidabadi, and O. Baghani, Solving an inverse problem for a time-fractional advection-diffusion equation with variable coefficients by rationalized Haar wavelet method, J. Comput Sci. 64 (2022), p. 101869.
  • M.A. Firoozjaee and S.A. Yousefi, A numerical approach for fractional partial differential equations by using Ritz approximation, Appl. Math. Comput. 338 (2018), pp. 711–721.
  • J. Hajishafieiha and S. Abbasbandy, Numerical solution of two-dimensional inverse time-fractional diffusion problem with non-local boundary condition using a-polynomials, J. Appl. Math. Comput. 69 (2023), pp. 1945–1965.
  • H. Hassani and Z. Avazzadeh, Novel operational matrices for solving 2-dim nonlinear variable order fractional optimal control problems via a new set of basis functions, Appl. Numer. Math. 166 (2021), pp. 26–39.
  • H. Hassani, Z. Avazzadeh, P. Agarwal, S. Mehrabi, M.J. Ebadi, M.S. Dahaghin, and E. Naraghirad, A study on fractional tumor-immune interaction model related to lung cancer via generalized Laguerre polynomials, BMC Med. Res. Methodol. 23(1) (2023), p. 189.
  • H. Hassani, J.A.T. Machado, E. Naraghirad, and Z. Avazzadeh, Optimal solution of a general class of nonlinear system of fractional partial differential equations using hybrid functions, Eng. Comput. 39 (2023), pp. 2401–2431.
  • E. Hesameddini and M. Shahbazi, Two-dimensional shifted Legendre polynomials operational matrix method for solving the two-dimensional integral equations of fractional order, Appl. Math. Comput. 322 (2018), pp. 40–54.
  • M.H. Heydari, Z. Avazzadeh, and Y. Yang, A computational method for solving variable-order fractional nonlinear diffusion-wave equation, Appl. Math. Comput. 352 (2019), pp. 235–248.
  • W. Hu, Z. Fu, Z. Tang, and Y. Gu, A meshless collocation method for solving the inverse Cauchy problem associated with the variable-order fractional heat conduction model under functionally graded materials, Eng. Anal. Bound. Elem. 140 (2022), pp. 132–144.
  • C. Ionescu, A. Lopes, D. Copot, J.T. Machado, and J.H. Bates, The role of fractional calculus in modeling biological phenomena: A review, Commun. Nonlinear Sci. Numer. Simul. 51 (2017), pp. 141–159.
  • H. Jafari, M.T. Malinowski, and M.J. Ebadi, Fuzzy stochastic differential equations driven by fractional Brownian motion, Adv. Differ. Equations 1 (2021), pp. 1–17.
  • A. Janmohammadi, J. Damirchi, S.M. Mahmoudi, and A. Esfandiari, Numerical solutions of inverse time fractional coupled Burgers' equations by the Chebyshev wavelet method, J. Appl. Math. Comput. 68 (2022), pp. 2983–3009.
  • M. Javidi and M. Saedshoar Heris, New numerical methods for solving the partial fractional differential equations with uniform and non-uniform meshes, J. Supercomput. 79 (2023), pp. 14457–14488.
  • J. Lai, F. Liu, V.V. Anh, and Q. Liu, A space-time finite element method for solving linear Riesz space fractional partial differential equations, Numer. Algor. 88 (2021), pp. 499–520.
  • J. Lin, Simulation of 2D and 3D inverse source problems of nonlinear time-fractional wave equation by the meshless homogenization function method, Eng. Comput. 38 (2021), pp. 3599–3608.
  • F.S. Lobato, W.J. Lima, R.A. Borges, A. Cavalini Jr, and V. Steffen Jr, The solution of direct and inverse fractional advection-dispersion problems by using orthogonal collocation and differential evolution, Soft Comput. 24 (2020), pp. 10389–10399.
  • T. Molaee and A. Shahrezaee, Numerical solution of an inverse source problem for a time-fractional PDE via direct meshless local Petrov-Galerkin method, Eng. Anal. Bound. Elem. 138 (2022), pp. 211–218.
  • M. Nawaz Khan, S-ul-Islam, I. Hussain, I. Ahmad, and H. Ahmad, A local meshless method for the numerical solution of space-dependent inverse heat problems, Math Methods. Appl. Sci. 44(4) (2021), pp. 3066–3079.
  • O. Postavaru, An efficient numerical method based on Fibonacci polynomials to solve fractional differential equations, Math. Comput. Simul. 212 (2023), pp. 406–422.
  • S. Qasemi, D. Rostamy, and N. Abdollahi, The time-fractional diffusion inverse problem subject to an extra measurement by a local discontinuous Galerkin method, Bit Numer. Math. 59 (2019), pp. 183–212.
  • L. Qiu, C. Hu, and Q-H. Qin, A novel homogenization function method for inverse source problem of nonlinear time-fractional wave equation, Appl Math. Lett. 109 (2020), pp. 106–554.
  • M. Radmanesh and M.J. Ebadi, A local mesh-less collocation method for solving a class of time-dependent fractional integral equations: 2D fractional evolution equation, Eng Anal. Bound. Elem. 113 (2020), pp. 372–381.
  • K. Rashedi, A numerical solution of an inverse diffusion problem based on operational matrices of orthonormal polynomials, Math Methods. Appl. Sci. 44(17) (2021), pp. 12980–12997.
  • M.K. Rawani, A.K. Verma, and C. Cattani, A novel hybrid approach for computing numerical solution of the time-fractional nonlinear one and two-dimensional partial integro-differential equation, Commun. Nonlinear Sci. Numer. Simul. 118 (2023), p. 106986.
  • M.G. Sakar and O. Saldır, Improving variational iteration method with auxiliary parameter for nonlinear time-fractional partial differential equations, J. Optim. Theory Appl. 174 (2017), pp. 530–549.
  • T. Shojaeizadeh, M. Mahmoudi, and M. Darehmiraki, Optimal control problem of advection-diffusion-reaction equation of kind fractal-fractional applying shifted Jacobi polynomials, Chaos, Solitons Fractals 143 (2021), p. 110568.
  • N. Srivastava, A. Singh, Y. Kumar, and V. Singh, Efficient numerical algorithms for Riesz-space fractional partial differential equations based on finite difference/operational matrix, Appl. Numer. Math. 161 (2021), pp. 244–274.
  • L. Su, J. Huang, V.I. Vasil'ev, A. Li, and A.M. Kardashevsky, A numerical method for solving retrospective inverse problem of fractional parabolic equation, J. Comput Appl. Math. 413 (2022), p. 114366.
  • H. Sun, Y. Zhang, D. Baleanu, W. Chen, and Y. Chen, A new collection of real world applications of fractional calculus in science and engineering, Commun. Nonlinear Sci. Numer. Simul. 64 (2018), pp. 213–231.
  • K. Taneja, K. Deswal, and D. Kumar, A robust higher-order numerical technique with graded and harmonic meshes for the time-fractional diffusion-advection-reaction equation, Math. Comput. Simul. 47 (2023), pp. 1649–1664.
  • J. Xie, Numerical computation of fractional partial differential equations with variable coefficients utilizing the modified fractional Legendre wavelets and error analysis, Math Methods. Appl. Sci. 44(8) (2021), pp. 7150–7164.
  • Y. Xing and Y. Yan, A higher order numerical method for time fractional partial differential equations with nonsmooth data, J. Comput Phys. 357 (2018), pp. 305–323.
  • X. Yang, X. Jiang, and H. Zhang, A time-space spectral tau method for the time fractional cable equation and its inverse problem, Appl Numer. Math. 130 (2018), pp. 95–111.
  • M.A. Zaky, A.S. Hendy, and J.E. Macías-Díaz, High-order finite difference/spectral-Galerkin approximations for the nonlinear time-space fractional Ginzburg-Landau equation, Numerical Methods Partial Differ. Equations 39 (2023), pp. 4549–4574.

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