Towards solving linear fractional differential equations with Hermite operational matrix

被引:0
作者
Kosunalp, Hatice Yalman [1 ]
Gulsu, Mustafa [2 ]
机构
[1] Bandirma Onyedi Eylul Univ, Gonen Vocat Sch, Dept Accounting & Tax, Balikesir, Turkiye
[2] Mugla Sitki Kocman Univ, Fac Sci, Math Dept, Mugla, Turkiye
来源
ADVANCED STUDIES-EURO-TBILISI MATHEMATICAL JOURNAL | 2023年 / 16卷 / 02期
关键词
fractional differential equations; hermite; operational matrix; caputo; TRAVELING-WAVE SOLUTIONS; HOMOTOPY ANALYSIS METHOD;
D O I
10.32513/asetmj/193220082316
中图分类号
O1 [数学];
学科分类号
0701 ; 070101 ;
摘要
This paper presents the derivation of a new operational matrix of Caputo fractional derivatives through Hermite polynomials with Tau method to solve a set of fractional differential equations (FDEs). The proposed algorithm is intended to solve linear type of FDEs with the pre-defined conditions into a matrix form for redefining the complete problem as a system of a algebraic equations.The proposed strategy is then applied to solve the simplified FDEs in linear form. To assess the performance of the proposed method, exact and approximate solutions for a number of illustrative examples are obtained which prove the effectiveness of the idea.
引用
收藏
页码:47 / 61
页数:15
相关论文
共 25 条
[1]  
Abdelkawy M.A., 2014, Walailak J. Sci. Technol.(WJST), V11, P1041
[2]  
Ahmadian A., 2013, ABSTR APPL ANAL, P1
[3]   A collocation-shooting method for solving fractional boundary value problems [J].
Al-Mdallal, Qasem M. ;
Syam, Muhammed I. ;
Anwar, M. N. .
COMMUNICATIONS IN NONLINEAR SCIENCE AND NUMERICAL SIMULATION, 2010, 15 (12) :3814-3822
[4]   Propagation of harmonic waves in a cylindrical rod via generalized Pochhammer-Chree dynamical wave equation [J].
Ali, Asghar ;
Seadawy, Aly R. ;
Baleanu, Dumitru .
RESULTS IN PHYSICS, 2020, 17
[5]  
BAILLIE RT, 1996, J ECONOMETRICS, V73
[6]  
Belgacem R, 2018, Gen Lett Math, V5, P32
[7]  
Bhrawy A. H., 2012, ADV DIFFER EQU-NY
[8]   Fractional diffusion in the multiple-trapping regime and revision of the equivalence with the continuous-time random walk [J].
Bisquert, J .
PHYSICAL REVIEW LETTERS, 2003, 91 (01)
[9]   Numerical solutions of multi-order fractional differential equations by Boubaker Polynomials [J].
Bolandtalat, A. ;
Babolian, E. ;
Jafari, H. .
OPEN PHYSICS, 2016, 14 (01) :226-230
[10]   Fractional integro-differential calculus and its control-theoretical applications. I. Mathematical fundamentals and the problem of interpretation [J].
Butkovskii, A. G. ;
Postnov, S. S. ;
Postnova, E. A. .
AUTOMATION AND REMOTE CONTROL, 2013, 74 (04) :543-574
123