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Solving fractal differential equations via fractal Laplace transforms

  • Karmina Kamal Ali , Alireza Khalili Golmankhaneh ORCID logo EMAIL logo , Resat Yilmazer and Milad Ashqi Abdullah
Published/Copyright: January 28, 2022
Journal of Applied Analysis
From the journal Journal of Applied Analysis Volume 28 Issue 2

Abstract

The intention of this study is to investigate the fractal version of both one-term and three-term fractal differential equations. The fractal Laplace transform of the local derivative and the non-local fractal Caputo derivative is applied to investigate the given models. The analogues of both the Wright function with its related definitions in fractal calculus and the convolution theorem in fractal calculus are proposed. All results in this paper have been obtained by applying certain tools such as the general Wright and Mittag-Leffler functions of three parameters and the convolution theorem in the sense of the fractal calculus. Moreover, a comparative analysis is conducted by solving the governing equation in the senses of the standard version and fractal calculus. It is obvious that when α = γ = β = 1 , we obtain the same results as in the standard version.

Keywords: Fractal calculus; fractal Wright function; fractal Laplace transform; fractal convolution theorem
MSC 2010: 28A80; 81Q35; 44A10

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Received: 2020-07-28
Revised: 2020-11-13
Accepted: 2021-02-20
Published Online: 2022-01-28
Published in Print: 2022-12-01

© 2022 Walter de Gruyter GmbH, Berlin/Boston

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https://doi.org/10.1515/jaa-2021-2076
Keywords for this article
Fractal calculus; fractal Wright function; fractal Laplace transform; fractal convolution theorem

Articles in the same Issue

  1. Frontmatter
  2. Estimates for a beam-like partial differential operator and applications
  3. Stabilization of polynomial systems in ℝ3 via homogeneous feedback
  4. Analyzing the existence of solution of a fractional order integral equation: A fixed point approach
  5. Existence of solution to a nonlocal biharmonic problem with dependence on gradient and Laplacian
  6. Global existence and exponential decay for a viscoelastic equation with not necessarily decreasing kernel
  7. Solving fractal differential equations via fractal Laplace transforms
  8. Minimum energy control of degenerate Cauchy problem with skew-Hermitian pencil
  9. Splines in vibration analysis of non-homogeneous circular plates of quadratic thickness
  10. The weak eigenfunctions of boundary-value problem with symmetric discontinuities
  11. Some subclasses of analytic functions involving certain integral operator
  12. Relation theoretic contractions and their applications in b-metric like spaces
  13. A new conservative finite difference scheme for 1D Cahn–Hilliard equation coupled with elasticity
  14. An improved proximal method with quasi-distance for nonconvex multiobjective optimization problem
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