The object of this paper devotes on offering an indirect scheme based on time-fractional Bernoulli functions in the sense of Rieman-Liouville fractional derivative which ends up to the high credit of the obtained approximate fractional Bessel solutions. In this paper, the operational matrices of fractional Rieman-Liouville integration for Bernoulli polynomials are introduced. Utilizing these operational matrices along with the properties of Bernoulli polynomials and the least squares method, the fractional Bessel differential equation converts into a nonlinear system of algebraic. To solve these nonlinear algebraic equations which are a prominent the problem, there is a need to employ Newton’s iterative method. In order to elaborate the study, the synergy of the proposed method is investigated and then the accuracy and the efficiency of the method are clearly evaluated by presenting numerical results.
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Tavan, S., Jahangiri Rad, M., Salimi Shamloo, A., & Mahmoudi, Y. (2022). A numerical scheme for solving time-fractional Bessel differential equations. Computational Methods for Differential Equations, 10(4), 1097-1114. doi: 10.22034/cmde.2021.45407.1910
MLA
Saber Tavan; Mohammad Jahangiri Rad; Ali Salimi Shamloo; Yaghoub Mahmoudi. "A numerical scheme for solving time-fractional Bessel differential equations". Computational Methods for Differential Equations, 10, 4, 2022, 1097-1114. doi: 10.22034/cmde.2021.45407.1910
HARVARD
Tavan, S., Jahangiri Rad, M., Salimi Shamloo, A., Mahmoudi, Y. (2022). 'A numerical scheme for solving time-fractional Bessel differential equations', Computational Methods for Differential Equations, 10(4), pp. 1097-1114. doi: 10.22034/cmde.2021.45407.1910
VANCOUVER
Tavan, S., Jahangiri Rad, M., Salimi Shamloo, A., Mahmoudi, Y. A numerical scheme for solving time-fractional Bessel differential equations. Computational Methods for Differential Equations, 2022; 10(4): 1097-1114. doi: 10.22034/cmde.2021.45407.1910
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