Abstract
In this study, a general formulation for the fractional-order general Lagrange scaling functions (FGLSFs) is introduced. These functions are employed for solving a class of fractional differential equations and a particular class of fractional delay differential equations. For this approach, we derive FGLSFs fractional integration and delay operational matrices. These operational matrices and collocation method are utilized to reduce each of the problems to a system of algebraic equation, which can be solve employing Newton’s iterative method. We indicate convergence of this method. Finally, some illustrative examples in order to observe the validity, effectiveness and accuracy of the present technique are included. Also, by applying this method, we solve the mathematical model of the noise effect on the laser device.
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Sabermahani, S., Ordokhani, Y. & Yousefi, S.A. Fractional-order general Lagrange scaling functions and their applications. Bit Numer Math 60, 101–128 (2020). https://doi.org/10.1007/s10543-019-00769-0
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DOI: https://doi.org/10.1007/s10543-019-00769-0
Keywords
- Fractional-order general Lagrange scaling function
- Fractional-order Lagrange polynomial
- General Lagrange scaling function
- Operational matrix
- Laplace transform