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A. Arikoglu and I. Ozkol, 1. (2007), Solution of fractional differential equations by using differential transform method, Chaos, Solitons and Fractals, 34, 1473–1481.ArikogluA.OzkolI.1.2007Solution of fractional differential equations by using differential transform methodChaos, Solitons and Fractals341473148110.1016/j.chaos.2006.09.004Search in Google Scholar
G. Dilek. Kk, M. Yigider and E. Çelik, 2. (2014), Numerical Solution of Fractional Partial Differential-Algebraic Equation by Adomian Decomposition Method and Multivariate Pade Approximation, British Journal of Applied Science & Technology, 4(25), 3653–3664.G. DilekKkYigiderM.ÇelikE.2.2014Numerical Solution of Fractional Partial Differential-Algebraic Equation by Adomian Decomposition Method and Multivariate Pade ApproximationBritish Journal of Applied Science & Technology4253653366410.9734/BJAST/2014/9941Search in Google Scholar
MJ. Jang, CL. Chen, YC. Liu, 3. (2001), Two- dimensional differential transform for Partial differential equations, Appl. Math. Comput., 121, 261–270.JangMJ.ChenCL.LiuYC.3.2001Two- dimensional differential transform for Partial differential equationsAppl. Math. Comput.12126127010.1016/S0096-3003(99)00293-3Search in Google Scholar
F. Kangalgil, F. Ayaz, 4. (2009), Solitary wave solutions for the KdV and mKdV equations by differential transform method Chaos Solitons Fractals, 41(1), 464–472.KangalgilF.AyazF.4.2009Solitary wave solutions for the KdV and mKdV equations by differential transform method Chaos Solitons Fractals41146447210.1016/j.chaos.2008.02.009Search in Google Scholar
KSV. Ravi, K. Aruna, 5. (2009), Two-dimensional differential transform method for solving linear and non-linear Schrdinger equations, Chaos Solitons Fractals, 41(5), 2277–2281.RaviKSV.ArunaK.5.2009Two-dimensional differential transform method for solving linear and non-linear Schrdinger equationsChaos Solitons Fractals4152277228110.1016/j.chaos.2008.08.037Search in Google Scholar
K. Tabatabaei, E. Çelik, and R. Tabatabaei, 6. (2012), Solving heat-like and wave-like equations by the differential transform method, Turk J Phys, 36, 87–98.TabatabaeiK.ÇelikE.TabatabaeiR.6.2012Solving heat-like and wave-like equations by the differential transform methodTurk J Phys368798Search in Google Scholar
Hatıra Günerhan, 7. (2019), Numerical Method for the Solution of Logistic Differential Equations of Fractional Order, Turkish Journal of Analysis and Number Theory, 7(2), 33–36.GünerhanHatıra7.2019Numerical Method for the Solution of Logistic Differential Equations of Fractional OrderTurkish Journal of Analysis and Number Theory72333610.12691/tjant-7-2-1Search in Google Scholar
F. Ayaz, 8. (2004), Solutions of the system of differential equations by differential transform method. Appl. Math. Comput. 147, 547–567.AyazF.8.2004Solutions of the system of differential equations by differential transform methodAppl. Math. Comput14754756710.1016/S0096-3003(02)00794-4Search in Google Scholar
F. Ayaz, 9. (2004), Applications of differential transform method to differential-algebraic equations, Appl. Math. Comput., 152, 649–657.AyazF.9.2004Applications of differential transform method to differential-algebraic equationsAppl. Math. Comput.15264965710.1016/S0096-3003(03)00581-2Search in Google Scholar
I.H. Abdel-Halim Hassan, 10. (2008), Application to differential transformation method for solving systems of differential equations, Appl. Math. Modell. 32(12), 2552–2559.Abdel-Halim HassanI.H.10.2008Application to differential transformation method for solving systems of differential equationsAppl. Math. Modell32122552255910.1016/j.apm.2007.09.025Search in Google Scholar
A. Yoku S. Glbahar, 11. (2019), Numerical Solutions with Linearization Techniques of the Fractional Harry Dym Equation, Applied Mathematics and Nonlinear Sciences, 4(1), 35–42.YokuA.GlbaharS.11.2019Numerical Solutions with Linearization Techniques of the Fractional Harry Dym EquationApplied Mathematics and Nonlinear Sciences41354210.2478/AMNS.2019.1.00004Search in Google Scholar
D. W. Brzeziski, 12. (2018), Review of numerical methods for NumILPT with computational accuracy assessment for fractional calculus,Applied Mathematics and Nonlinear Sciences,3(2), 487–502.BrzeziskiD. W.12.2018Review of numerical methods for NumILPT with computational accuracy assessment for fractional calculusApplied Mathematics and Nonlinear Sciences3248750210.2478/AMNS.2018.2.00038Search in Google Scholar
D. W. Brzeziski, 13. (2017), Comparison of Fractional Order Derivatives Computational Accuracy - Right Hand vs Left Hand Definition, Applied Mathematics and Nonlinear Sciences, 2(1), 237–248.BrzeziskiD. W.13.2017Comparison of Fractional Order Derivatives Computational Accuracy - Right Hand vs Left Hand DefinitionApplied Mathematics and Nonlinear Sciences2123724810.21042/AMNS.2017.1.00020Search in Google Scholar
I. K., Youssef, & M. H. El Dewaik, 14. (2017), Solving Poisson’s Equations with fractional order using Haarwavelet, Applied Mathematics and Nonlinear Sciences, 2(1), 271–284.YoussefI. K.El DewaikM. H.14.2017Solving Poisson’s Equations with fractional order using HaarwaveletApplied Mathematics and Nonlinear Sciences2127128410.21042/AMNS.2017.1.00023Search in Google Scholar
M.T. Genoglu, H.M. Baskonus, & H. Bulut, 15. (2017), Numerical simulations to the nonlinear model of interpersonal relationships with time fractional derivative, AIP Conf. Proc., 1798, (020103), 1–9.GenogluM.T.BaskonusH.M.BulutH.15.2017Numerical simulations to the nonlinear model of interpersonal relationships with time fractional derivativeAIP Conf. Proc.1798(020103),1910.1063/1.4972695Search in Google Scholar
D. Kumar, J. Singh, H. M. Baskonus, et al., 16. (2017), An Effective Computational Approach for Solving Local Fractional Telegraph Equations, Nonlinear Science Letters A: Mathematics, Physics and Mechanics, 8(2), 200–206.KumarD.SinghJ.BaskonusH. M.16.2017An Effective Computational Approach for Solving Local Fractional Telegraph Equations, Nonlinear Science Letters A: MathematicsPhysics and Mechanics82200206Search in Google Scholar
