Vieta-Lucas polynomials for solving a fractional-order mathematical physics model

被引:55
作者
Agarwal, P. [1 ,2 ]
El-Sayed, A. A. [3 ,4 ]
机构
[1] Int Ctr Basic & Appl Sci, Jaipur 302029, Rajasthan, India
[2] Anand Int Coll Engn, Dept Math, Jaipur, India
[3] Minist Higher Educ, Rustaq Coll Educ, Dept Math, Rustaq 329, Oman
[4] Fayoum Univ, Fac Sci, Dept Math, Al Fayyum 63514, Egypt
来源
ADVANCES IN DIFFERENCE EQUATIONS | 2020年 / 2020卷 / 01期
关键词
Advection– dispersion equation of the fractional-order; Caputo fractional-order operator; Vieta– Lucas polynomials; Spectral collocation method; Nonstandard finite difference method; ADVECTION-DISPERSION EQUATION; FINITE-DIFFERENCE; CHEBYSHEV POLYNOMIALS; DIFFUSION-EQUATIONS; OPERATIONAL MATRIX; NUMERICAL-SOLUTION;
D O I
10.1186/s13662-020-03085-y
中图分类号
O29 [应用数学];
学科分类号
070104 ;
摘要
In this article, a fractional-order mathematical physics model, advection-dispersion equation (FADE), will be solved numerically through a new approximative technique. Shifted Vieta-Lucas orthogonal polynomials will be considered as the main base for the desired numerical solution. These polynomials are used for transforming the FADE into an ordinary differential equations system (ODES). The nonstandard finite difference method coincidence with the spectral collocation method will be used for converting the ODES into an equivalence system of algebraic equations that can be solved numerically. The Caputo fractional derivative will be used. Moreover, the error analysis and the upper bound of the derived formula error will be investigated. Lastly, the accuracy and efficiency of the proposed method will be demonstrated through some numerical applications.
引用
收藏
页数:18
相关论文
共 38 条
[1]   Vieta-Fibonacci operational matrices for spectral solutions of variable-order fractional integro-differential equations [J].
Agarwal, P. ;
El-Sayed, A. A. ;
Tariboon, J. .
JOURNAL OF COMPUTATIONAL AND APPLIED MATHEMATICS, 2021, 382
[2]   Non-standard finite difference and Chebyshev collocation methods for solving fractional diffusion equation [J].
Agarwal, P. ;
El-Sayed, A. A. .
PHYSICA A-STATISTICAL MECHANICS AND ITS APPLICATIONS, 2018, 500 :40-49
[3]   Application of a fractional advection-dispersion equation [J].
Benson, DA ;
Wheatcraft, SW ;
Meerschaert, MM .
WATER RESOURCES RESEARCH, 2000, 36 (06) :1403-1412
[4]   Levy flights in a steep potential well [J].
Chechkin, AV ;
Gonchar, VY ;
Klafter, J ;
Metzler, R ;
Tanatarov, LV .
JOURNAL OF STATISTICAL PHYSICS, 2004, 115 (5-6) :1505-1535
[5]   Second kind Chebyshev operational matrix algorithm for solving differential equations of Lane-Emden type [J].
Doha, E. H. ;
Abd-Elhameed, W. M. ;
Youssri, Y. H. .
NEW ASTRONOMY, 2013, 23-24 :113-117
[6]   A novel Jacobi operational matrix for numerical solution of multi-term variable-order fractional differential equations [J].
El-Sayed, A. A. ;
Baleanu, D. ;
Agarwal, P. .
JOURNAL OF TAIBAH UNIVERSITY FOR SCIENCE, 2020, 14 (01) :963-974
[7]   Adomian's decomposition method for solving an intermediate fractional advection-dispersion equation [J].
El-Sayed, A. M. A. ;
Behiry, S. H. ;
Raslan, W. E. .
COMPUTERS & MATHEMATICS WITH APPLICATIONS, 2010, 59 (05) :1759-1765
[8]   Numerical solution of multiterm variable-order fractional differential equations via shifted Legendre polynomials [J].
El-Sayed, Adel A. ;
Agarwal, Praveen .
MATHEMATICAL METHODS IN THE APPLIED SCIENCES, 2019, 42 (11) :3978-3991
[9]   An exponential spline approximation for fractional Bagley-Torvik equation [J].
Emadifar, Homan ;
Jalilian, Reza .
BOUNDARY VALUE PROBLEMS, 2020, 2020 (01)
[10]   Analytical modelling of fractional advection-dispersion equation defined in a bounded space domain [J].
Golbabai, A. ;
Sayevand, K. .
MATHEMATICAL AND COMPUTER MODELLING, 2011, 53 (9-10) :1708-1718
1234