Solving high-order partial differential equations in unbounded domains by means of double exponential second kind Chebyshev approximation
Mohamed
Abd Elsalam
Mathematics Department, Faculty of Science
Al-Azhar University, Nasr-City, 11884, Cairo, Egypt
author
Mohamed
Ramadan
Mathematics Department, Faculty of Science, Menoufia University, Shebein El-Koom, Egypt
author
Kamal
Raslsn
Mathematics Department, Faculty of Science, Al-Azhar University, Nasr-City, Cairo, Egypt
author
Talaat
El Danaf
Department of Mathematics and Statistics, Taibah University Madinah Munawwarah, KSA
author
text
article
2015
eng
In this paper, a collocation method for solving high-order linear partial differential equations (PDEs) with variable coefficients under more general form of conditions is presented. This method is based on the approximation of the truncated double exponential second kind Chebyshev (ESC) series. The definition of the partial derivative is presented and derived as new operational matrices of derivatives. All principles and properties of the ESC functions are derived and introduced by us as a new basis defined in the whole range. The method transforms the PDEs and conditions into block matrix equations, which correspond to system of linear algebraic equations with unknown ESC coefficients, by using ESC collocation points. Combining these matrix equations and then solving the system yield the ESC coefficients of the solution function. Numerical examples are included to test the validity and applicability of the method.
Computational Methods for Differential Equations
University of Tabriz
2345-3982
3
v.
3
no.
2015
147
162
http://cmde.tabrizu.ac.ir/article_4716_865a972e969ce0256b6db9b8006f6073.pdf
ITERATIVE SCHEME TO A COUPLED SYSTEM OF HIGHLY NONLINEAR FRACTIONAL ORDER DIFFERENTIAL EQUATIONS
Kamal
Shah
University of Malakand
author
Rahmat
Khan
Derartment of Mathematcs University of Malakand KPK Pakistan
author
text
article
2015
eng
In this article, we investigate sufficient conditions for existence of maximal and minimalsolutions to a coupled system of highly nonlinear differential equations of fractional order with mixedtype boundary conditions. To achieve this goal, we apply monotone iterative technique togetherwith the method of upper and lower solutions. Also an error estimation is given to check theaccuracy of the method. We provide an example to illustrate our main results.
Computational Methods for Differential Equations
University of Tabriz
2345-3982
3
v.
3
no.
2015
163
176
http://cmde.tabrizu.ac.ir/article_4771_2caa42796fa9abd0485bb9672a8dd0b4.pdf
Solution of Bang-Bang Optimal Control Problems by Using Bezier Polynomials
Ayatollah
Yari
Payame Noor University
author
Mirkamal
Mirnia
University of Tabriz
author
Aghileh
Heydari
Payame Noor University
author
text
article
2015
eng
In this paper, a new numerical method is presented for solving the optimal control problems of Bang-Bang type with free or fixed terminal time. The method is based on Bezier polynomials which are presented in any interval as $[t_0,t_f]$. The problems are reduced to a constrained problems which can be solved by using Lagrangian method. The constraints of these problems are terminal state and conditions. Illustrative examples are included to demonstrate the validity and applicability of the method.
Computational Methods for Differential Equations
University of Tabriz
2345-3982
3
v.
3
no.
2015
177
191
http://cmde.tabrizu.ac.ir/article_4770_a00ee50be84f54611ea5e5335b492e2d.pdf
Explicit exact solutions for variable coefficient Broer-Kaup equations
Manjit
Singh
Yadavindra College of Engineering, Punjabi University Guru Kashi Campus, Talwandi Sabo
author
R.K.
Gupta
Central University of Punjab, Bathinda, Punjab, India.
author
text
article
2015
eng
Based on symbolic manipulation program Maple and using Riccati equation mapping method several explicit exact solutions including kink, soliton-like, periodic and rational solutions are obtained for (2+1)-dimensional variable coefficient Broer-Kaup system in quite a straightforward manner. The known solutions of Riccati equation are used to construct new solutions for variable coefficient Broer-Kaup system.
Computational Methods for Differential Equations
University of Tabriz
2345-3982
3
v.
3
no.
2015
192
199
http://cmde.tabrizu.ac.ir/article_4774_835457e718ceb27933e9085f35bb7eb9.pdf
An application of differential transform method for solving nonlinear optimal control problems
Alireza
Nazemi
Faculty of math shahrood university.
author
text
article
2015
eng
In this paper, we present a capable algorithm for solving a class of nonlinear optimal control problems (OCP's). The approach rest mainly on the differential transform method (DTM) which is one of the approximate methods. The DTM is a powerful and efficient technique for finding solutions of nonlinear equations without the need of a linearization process. Utilizing this approach, the optimal control and the corresponding trajectory of the OCP's are found in the form of rapidly convergent series with easily computed components. Numerical results are also given for several test examples to demonstrate the applicability and the efficiency of the method.
Computational Methods for Differential Equations
University of Tabriz
2345-3982
3
v.
3
no.
2015
200
217
http://cmde.tabrizu.ac.ir/article_4972_22d60c5610c1acd953ee761bc55ca38e.pdf
Non-polynomial Spline Method for Solving Coupled Burgers Equations
Khalid
K. Ali
department of mathematics, faculty of since, al-azhar univesity
author
Kamal
Raslan
Mathematics Department, Faculty of Science, Al-Azhar University, Nasr-City, Cairo, Egypt.
author
Talaat
El Danaf
Mathematics Department, Faculty of Science, Menoufia University, Shebein El-Koom, Egypt.
author
text
article
2015
eng
In this paper, non-polynomial spline method for solving Coupled Burgers Equations are presented. We take a new spline function. The stability analysis using Von-Neumann technique shows the scheme is unconditionally stable. To test accuracy the error norms 2L, L are computed and give two examples to illustrate the sufficiency of the method for solving such nonlinear partial differential equations. These results show that the technique introduced here is accurate and easy to apply.
Computational Methods for Differential Equations
University of Tabriz
2345-3982
3
v.
3
no.
2015
218
230
http://cmde.tabrizu.ac.ir/article_4974_e3d373c5ccd58d93abdaae09981caee2.pdf