On an inequality of G. H. Hardy.
Iqbal, Sajid, Krulić, Kristina, Pečarić, Josip (2010)
Journal of Inequalities and Applications [electronic only]
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Displaying similar documents to “Solution of an extraordinary differential equation by Adomian decomposition method.”
On an inequality of G. H. Hardy.
The foam drainage equation with time and space-fractional derivatives solved by the adomian method.
Dahmani, Z., Mesmoudi, M.M., Bebbouchi, R. (2008)
Electronic Journal of Qualitative Theory of Differential Equations [electronic only]
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Abstract differential equations of arbitrary (fractional) orders
El-Sayed, Ahmed M. A.
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Solitary wave solutions for a time-fraction generalized Hirota-Satsuma coupled KdV equation by a new analytical technique.
Shateri, Majid, Ganji, D.D. (2010)
International Journal of Differential Equations
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Recent applications of fractional calculus to science and engineering.
Debnath, Lokenath (2003)
International Journal of Mathematics and Mathematical Sciences
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Boundary value problems for differential equations with fractional order.
Benchohra, Mouffak, Hamani, Samira, Ntouyas, Sotiris K. (2008)
Surveys in Mathematics and its Applications
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A constructive approach for solving system of fractional differential equations
H.R. Marasi, Vishnu Narayan Mishra, M. Daneshbastam (2017)
Waves, Wavelets and Fractals
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In this paper to solve a set of linear and nonlinear fractional differential equations, we modified the differential transform method. Adomian polynomials helped taking care of the non-linear terms. The main advantage of our algorithm over the numerical methods is being able to solve nonlinear systems without any discretization or restrictive assumption. We considered Caputo definition for fractional derivatives.
From Newton's equation to fractional diffusion and wave equations.
Vázquez, Luis (2011)
Advances in Difference Equations [electronic only]
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On contraction principle applied to nonlinear fractional differential equations with derivatives of order α ∈ (0,1)
Małgorzata Klimek (2011)
Banach Center Publications
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One-term and multi-term fractional differential equations with a basic derivative of order α ∈ (0,1) are solved. The existence and uniqueness of the solution is proved by using the fixed point theorem and the equivalent norms designed for a given value of parameters and function space. The explicit form of the solution obeying the set of initial conditions is given.
Note on the fractional parts of λθⁿ
Masayoshi Hata (2005)
Acta Arithmetica
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On fractional derivatives
Helena Musielak (1973)
Colloquium Mathematicae
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Theorems on some families of fractional differential equations and their applications
Gülçin Bozkurt, Durmuş Albayrak, Neşe Dernek (2019)
Applications of Mathematics
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We use the Laplace transform method to solve certain families of fractional order differential equations. Fractional derivatives that appear in these equations are defined in the sense of Caputo fractional derivative or the Riemann-Liouville fractional derivative. We first state and prove our main results regarding the solutions of some families of fractional order differential equations, and then give examples to illustrate these results. In particular, we give the exact solutions for...