The bivariate Muntz wavelets composite collocation method for solving space-time-fractional partial differential equations

被引:15
作者
Rahimkhani, Parisa [1 ]
Ordokhani, Yadollah [1 ]
机构
[1] Alzahra Univ, Fac Math Sci, Dept Math, Tehran, Iran
来源
COMPUTATIONAL & APPLIED MATHEMATICS | 2020年 / 39卷 / 02期
关键词
Bivariate Muntz-Legendre wavelets; Composite collocation method; Caputo derivative; Numerical technique; FINITE DIFFERENCE/SPECTRAL APPROXIMATIONS; NUMERICAL-SOLUTION; OPERATIONAL MATRIX; INTEGRODIFFERENTIAL EQUATIONS; DIFFUSION EQUATIONS; BERNOULLI WAVELETS; LEGENDRE WAVELETS; ELEMENT METHOD; ERROR ESTIMATE; DERIVATIVES;
D O I
10.1007/s40314-020-01141-7
中图分类号
O29 [应用数学];
学科分类号
070104 ;
摘要
Herein, we consider an effective numerical scheme for numerical evaluation of three classes of space-time-fractional partial differential equations (FPDEs). We are going to solve these problems via composite collocation method. The procedure is based upon the bivariate Muntz-Legendre wavelets (MLWs). The bivariate Muntz-Legendre wavelets are constructed for first time. The bivariate MLWs operational matrix of fractional-order integral is constructed. The proposed scheme transforms FPDEs to the solution of a system of algebraic equations which these systems will be solved using the Newton's iterative scheme. Also, the error analysis of the suggested procedure is determined. To test the applicability and validity of our technique, we have solved three classes of FPDEs.
引用
收藏
页数:23
相关论文
共 51 条
[1]   Fifth-kind orthonormal Chebyshev polynomial solutions for fractional differential equations [J].
Abd-Elhameed, W. M. ;
Youssri, Y. H. .
COMPUTATIONAL & APPLIED MATHEMATICS, 2018, 37 (03) :2897-2921
[2]   Solving systems of fractional differential equations by homotopy-perturbation method [J].
Abdulaziz, O. ;
Hashim, I. ;
Momani, S. .
PHYSICS LETTERS A, 2008, 372 (04) :451-459
[3]   Long memory processes and fractional integration in econometrics [J].
Baillie, RT .
JOURNAL OF ECONOMETRICS, 1996, 73 (01) :5-59
[4]   Fractional calculus in hydrologic modeling: A numerical perspective [J].
Benson, David A. ;
Meerschaert, Mark M. ;
Revielle, Jordan .
ADVANCES IN WATER RESOURCES, 2013, 51 :479-497
[5]   FAST WAVELET TRANSFORMS AND NUMERICAL ALGORITHMS .1. [J].
BEYLKIN, G ;
COIFMAN, R ;
ROKHLIN, V .
COMMUNICATIONS ON PURE AND APPLIED MATHEMATICS, 1991, 44 (02) :141-183
[6]   A method based on the Jacobi tau approximation for solving multi-term time-space fractional partial differential equations [J].
Bhrawy, A. H. ;
Zaky, M. A. .
JOURNAL OF COMPUTATIONAL PHYSICS, 2015, 281 :876-895
[7]   A SPECTRAL LEGENDRE-GAUSS-LOBATTO COLLOCATION METHOD FOR A SPACE-FRACTIONAL ADVECTION DIFFUSION EQUATIONS WITH VARIABLE COEFFICIENTS [J].
Bhrawy, A. H. ;
Baleanu, D. .
REPORTS ON MATHEMATICAL PHYSICS, 2013, 72 (02) :219-233
[8]   Analog fractional order controller in temperature and motor control applications [J].
Bohannan, Gary W. .
JOURNAL OF VIBRATION AND CONTROL, 2008, 14 (9-10) :1487-1498
[9]  
Bulirsch R., 2002, Introduction to numerical analysis, V3
[10]   Numerical solution of fractional partial differential equations with variable coefficients using generalized fractional-order Legendre functions [J].
Chen, Yiming ;
Sun, Yannan ;
Liu, Liqing .
APPLIED MATHEMATICS AND COMPUTATION, 2014, 244 :847-858
123456