Numerical solutions for systems of fractional order differential equations with Bernoulli wavelets

被引:12
|
作者
Wang, Jiao [1 ]
Xu, Tian-Zhou [1 ]
Wei, Yan-Qiao [2 ]
Xie, Jia-Quan [3 ]
机构
[1] Beijing Inst Technol, Sch Math & Stat, Beijing 100081, Peoples R China
[2] Univ Orleans, INSA Ctr Val Loire, Bourges, France
[3] Taiyuan Univ Sci & Technol, Coll Mech Engn, Taiyuan, Shanxi, Peoples R China
来源
INTERNATIONAL JOURNAL OF COMPUTER MATHEMATICS | 2019年 / 96卷 / 02期
关键词
Bernoulli wavelets; fractional integral operator matrix; systems of fractional order differential equations; numerical solutions; convergence analysis; OPERATIONAL MATRIX; COUPLED SYSTEM; ADOMIAN DECOMPOSITION; CONVERGENCE;
D O I
10.1080/00207160.2018.1438604
中图分类号
O29 [应用数学];
学科分类号
070104 ;
摘要
In this paper, an effective algorithm for solving systems of fractional order differential equations (FDEs) is proposed. The algorithm is based on Bernoulli wavelets function approximation, which has never been used for systems of FDEs. The main purpose of this algorithm is to combine Bernoulli wavelets function approximation with its fractional integral operator matrix to transform the studied systems of fractional differential equations into easily solved systems of algebraic equations. Illustrative examples are included to reveal the effectiveness of the algorithm and the accuracy of the convergence analysis.
引用
收藏
页码:317 / 336
页数:20
相关论文
共 50 条
  • [21] A numerical method based on fractional-order generalized Taylor wavelets for solving distributed-order fractional partial differential equations
    Yuttanan, Boonrod
    Razzaghi, Mohsen
    Vo, Thieu N.
    APPLIED NUMERICAL MATHEMATICS, 2021, 160 : 349 - 367
  • [22] Numerical solutions of multi-order fractional differential equations by Boubaker Polynomials
    Bolandtalat, A.
    Babolian, E.
    Jafari, H.
    OPEN PHYSICS, 2016, 14 (01): : 226 - 230
  • [23] A Numerical Technique Based on Bernoulli Wavelet Operational Matrices for Solving a Class of Fractional Order Differential Equations
    Arafa, Heba M.
    Ramadan, Mohamed A.
    Althobaiti, Nesreen
    FRACTAL AND FRACTIONAL, 2023, 7 (08)
  • [24] Numerical solution of fractional partial differential equations using Haar wavelets
    Wang, Lifeng
    Meng, Zhijun
    Ma, Yunpeng
    Wu, Zeyan
    CMES-COMPUTER MODELING IN ENGINEERING & SCIENCES, 2013, 91 (04): : 269 - 287
  • [25] A numerical method for fractional pantograph differential equations based on Taylor wavelets
    Vichitkunakorn, Panupong
    Thieu N Vo
    Razzaghi, Mohsen
    TRANSACTIONS OF THE INSTITUTE OF MEASUREMENT AND CONTROL, 2020, 42 (07) : 1334 - 1344
  • [26] New Ultraspherical Wavelets Spectral Solutions for Fractional Riccati Differential Equations
    Abd-Elhameed, W. M.
    Youssri, Y. H.
    ABSTRACT AND APPLIED ANALYSIS, 2014,
  • [27] An improved composite collocation method for distributed-order fractional differential equations based on fractional Chelyshkov wavelets
    Rahimkhani, P.
    Ordokhani, Y.
    Lima, P. M.
    APPLIED NUMERICAL MATHEMATICS, 2019, 145 : 1 - 27
  • [28] A New Operational Matrix of Fractional Derivatives to Solve Systems of Fractional Differential Equations via Legendre Wavelets
    Secer, Aydin
    Altun, Selvi
    MATHEMATICS, 2018, 6 (11):
  • [29] Application of Legendre wavelets for solving fractional differential equations
    Jafari, H.
    Yousefi, S. A.
    Firoozjaee, M. A.
    Momani, S.
    Khalique, C. M.
    COMPUTERS & MATHEMATICS WITH APPLICATIONS, 2011, 62 (03) : 1038 - 1045
  • [30] Numerical solution of fractional differential equations using hybrid Bernoulli polynomials and block pulse functions
    Bo Zhang
    Yinggan Tang
    Xuguang Zhang
    Mathematical Sciences, 2021, 15 : 293 - 304
12345