scholarly journals Symbolic computation of exact solutions for fractional differential-difference equation models

2015 ◽  
Vol 20 (1) ◽  
pp. 112-131 ◽  
Author(s):  
Ismail Aslan ◽  
Keyword(s):  
Difference Equation ◽  
Exact Solutions ◽  
Symbolic Computation ◽  
Fractional Differential ◽  
Differential Difference Equation

Exact Solutions for Fractional Differential-Difference Equations by (G'/G)-Expansion Method with Modified Riemann-Liouville Derivative

2016 ◽  
Vol 8 (2) ◽  
pp. 293-305 ◽  
Author(s):  
Ahmet Bekir ◽  
Ozkan Guner ◽  
Burcu Ayhan ◽  
Adem C. Cevikel
Keyword(s):  
Difference Equation ◽  
Exact Solutions ◽  
Difference Equations ◽  
Applied Mathematics ◽  
Expansion Method ◽  
New Exact Solutions ◽  
Liouville Derivative ◽  
Nonlinear Lattice ◽  
Fractional Differential ◽  
Differential Difference Equation

AbstractIn this paper, the (G'/G)-expansion method is suggested to establish new exact solutions for fractional differential-difference equations in the sense of modified Riemann-Liouville derivative. The fractional complex transform is proposed to convert a fractional partial differential difference equation into its differential difference equation of integer order. With the aid of symbolic computation, we choose nonlinear lattice equations to illustrate the validity and advantages of the algorithm. It is shown that the proposed algorithm is effective and can be used for many other nonlinear lattice equations in mathematical physics and applied mathematics.

Differential-Difference Equation Arising in Nanotechnology and it's Exact Solutions

2013 ◽  
Vol 23 ◽  
pp. 113-116 ◽  
Author(s):  
Sheng Zhang ◽  
Qian An Zong ◽  
Qun Cao ◽  
Dong Liu
Keyword(s):  
Difference Equation ◽  
Exact Solutions ◽  
Continuum Hypothesis ◽  
Nanoporous Materials ◽  
Difference Model ◽  
Electron Conduction ◽  
New Exact Solutions ◽  
Alternative Approach ◽  
Differential Difference Equation ◽  
Model Equations

Differential-difference model equations are often considered as an alternative approach to describing some phenomena arising in heat/electron conduction and flow in carbon nanotubes and nanoporous materials, this is due to the fact that continuum hypothesis is no longer valid. A (2+1)-dimensional nonlinear differential-difference equation with an arbitrary function is introduced and new exact solutions are obtained.

N-soliton-like and double Casoratian solutions of a nonisospectral Ablowitz–Ladik equation

2016 ◽  
Vol 30 (28n29) ◽  
pp. 1640008
Author(s):  
Shou-Ting Chen ◽  
Qi Li ◽  
Deng-Yuan Chen ◽  
Jun-Wei Cheng
Keyword(s):  
Difference Equation ◽  
Exact Solutions ◽  
Spectral Problem ◽  
Bilinear Form ◽  
Direct Method ◽  
Dependent Variables ◽  
Differential Difference Equation ◽  
Bilinear Equation

A bilinear form of a nonisospectral differential-difference equation related to the Ablowitz–Ladik (AL) spectral problem is derived by a transformation of dependent variables. Exact solutions to the resulting bilinear equation are found. The [Formula: see text]-soliton-like solutions and the double Casoratian solutions are derived by means of Hirota’s direct method and the double Casoratian technique, respectively. Moreover, the connection between those two classes of solutions is explored.

scholarly journals Analytical and numerical results of fractional differential-difference equations

2015 ◽  
Vol 7 (2) ◽  
pp. 186-199 ◽  
Author(s):  
Najeeb Alam Khan ◽  
Fatima Riaz
Keyword(s):  
Difference Equation ◽  
Nonlinear Dynamical Systems ◽  
Linear Equations ◽  
Transformation Method ◽  
Test Problems ◽  
Nonlinear Dynamical ◽  
Fractional Differential ◽  
Differential Difference Equation ◽  
Sensitivity Approach ◽  
Infinite Linear

Abstract In this paper, we examine the fractional differential-difference equation (FDDE) by employing the proposed sensitivity approach (SA) and Adomian transformation method (ADTM). In SA the nonlinear differential-difference equation is converted to infinite linear equations which have a wide criterion to solve for the analytical solution. By ADTM, the FDDE is converted into ordinary differential-difference equation that can be solved. We test both the techniques through some test problems which are arising in nonlinear dynamical systems and found that ADTM is equivalently appropriate and simpler method to handle than SA.

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