Numerical Approximation of Higher-Order Time-Fractional Telegraph Equation by Using a Combination of a Geometric Approach and Method of Line
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Date
2016
Authors
Journal Title
Journal ISSN
Volume Title
Publisher
Academic Press inc Elsevier Science
Open Access Color
Green Open Access
No
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No
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Top 10%
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Top 10%
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Top 10%
Abstract
We propose a simple and accurate numerical scheme for solving the time fractional telegraph (TFT) equation within Caputo type fractional derivative. A fictitious coordinate v is imposed onto the problem in order to transform the dependent variable u(x, t) into a new variable with an extra dimension. In the new space with the added fictitious dimension, a combination of method of line and group preserving scheme (GPS) is proposed to find the approximate solutions. This method preserves the geometric structure of the problem. Power and accuracy of this method has been illustrated through some examples of TFT equation. (C) 2016 Elsevier Inc. All rights reserved.
Description
Hashemi, Mir Sajjad/0000-0002-5529-3125
ORCID
Keywords
Time-Fractional Telegraph Equation, Caputo Derivative, Fictitious Time Integration Method, Group Preserving Scheme, Method Of Line, Method of lines for initial value and initial-boundary value problems involving PDEs, group preserving scheme, time-fractional telegraph equation, Fractional partial differential equations, fictitious time integration method, method of line, Caputo derivative
Fields of Science
0103 physical sciences, 01 natural sciences
Citation
Hashemi, M.S., Baleanu, D. (2016). Numerical approximation of higher-order time-fractional telegraph equation by using a combination of a geometric approach and method of line. Journal of Computational Pyhsics, 316, 10-20. http://dx.doi.org/10.1016/j.jcp.2016.04.009
WoS Q
Q1
Scopus Q
Q1
OpenCitations Citation Count
62
Source
Journal of Computational Physics
Volume
316
Issue
Start Page
10
End Page
20
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CrossRef : 61
Scopus : 67
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Mendeley Readers : 13
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69
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4
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