- Open Access
- Total Downloads : 15
- Authors : T. R. Ramesh Rao
- Paper ID : IJERTCONV5IS13077
- Volume & Issue : ICONNECT – 2017 (Volume 5 – Issue 13)
- Published (First Online): 24-04-2018
- ISSN (Online) : 2278-0181
- Publisher Name : IJERT
- License: This work is licensed under a Creative Commons Attribution 4.0 International License
Exact Solutions of Some Nonlinear Partial Differential Equations Using Homotopy Perturbation Method Linked with Laplace Transforms and the Pade’s Approximants
T. R. Ramesh Rao
B. S. Abdur Rahman Crescent University Vandalur, Chennai 48.
Abstract: In this paper, obtaining exact solution of non linear partial differential equations by using Homotopy Perturbation method via Laplace transform and Pades Approximants. Numerical examples including Cauchy problem and non linear gas dynamics equation are given to show that the effectiveness of HPM-Lap-Pades technique.
AMS Subject classification: 35F20, 35F25
Keyword: Homotopy perturbation method, Laplace transforms, Pades approximants, Gas dynamics equation, Cauchy problem
deforms continuously to a simple problem.
The Homotopy perturbation method has been successfully applied to solve nonlinear Gas Dynamics equation [5], quadratic Riccati differential equation of fractional order [9], nonlinear heat conduction problems [7], Bratu type problems [8].
The basic idea of this method is the following. We consider the non linear differential equation
() () = 0
-
INTRODUCTION
In the recent years, much attention has been devoted to the newly developed methods to construct the
With boundary conditions
(, ) = 0,
(1)
(2)
analytic solution of first order non-linear partial differential equations which arise in gas dynamics, water waves, elastic dynamics, chemical reactions, transport of pollutants, flood waves in rivers, traffic flow and a wide range of biological and ecological systems. The non linear partial differential equations are generally difficult to solve and difficult to find their exact solution.
In this paper, the closed form of exact solution of non-linear partial differential equation is obtained by applying Laplace transform with pades approximants on the second order truncated solution series obtained by Homotopy perturbation method.
The numerical solution of first order nonlinear partial differential equation has been given considerable attention in recent years by introducing various methods and techniques. For example D.J.Evans et.al [1] used Decomposition method to investigate the solution of Gas Dynamics equation. This method provides the solution in a rapidly convergent series where the series may lead to the exact solution if it exists. Y.Keskin et.al [6] introduced Reduced Differential Transform method to find the approximate analytic solution to non linear partial differential equations.
-
BASIC IDEA OF HOMOTOPY PERTURBATION METHOD
The Homotopy perturbation method is powerful and efficient technique to find the solution of linear and nonlinear differential equations. This method was first introduced by He ([2], [3]).The method which is coupling of traditional perturbation and homotopy in topology
Where A is the general differential operator, B is the boundary operator and () is a known analytic function.
is the boundary of the domain
The operator A can be generally divided in to two parts L and N , where L is linear, whereas N is non linear. Therefore, Eq. (1) can be rewritten as follows:
() + () () = 0
(3)
Using homotopy technique, we construct the homotopy as:
(, ): [0,1] which satisfies:
(, ) = (1 )[() (0)] + [() ()] = 0, (4)
Where [0,1] is an embedding parameter and 0 is the first approximation that satisfy the boundary conditions. We can write this homotopy equation as follows:
(, ) = () (_0 ) + (_0 ) + (()
() ) = 0, (5) Obviously from Eqns. (4) and (5), we have
(, ) = () (0) = 0
(6)
(, 1) = () + () () = 0
(7)
The embedded parameter p monotonically changes from zero to unity as the trivial problem () (0) is continuously deformed to the original problem () . Due to the fact that [0,1]can be considered as a small
parameter, hence we consider the solution of Eqn.(4) as a power series in p as the following:
= 0 + 1 + 22 +
(8)
Setting = 1 results in the approximate solution for Eqn.(1)
() = lim = 0 + 1 + 2 +
1
Substituting the Eqns.(16), (17) and (18) in to the Eqn.(9) and truncate the series solution by second order perturbation ie. The approximate solution is:
=0
(, ) = 2 (, ) = 0 + 1 + 2 = 1 (1 + +
2) (19)
2
Taking the Laplace transform of the Eqn. (19)
[(, )] = 1 (1 + + )(9)
The series is convergent for most of the cases and rate of
(20)
2
3
convergence depend on (),(see [2])
For the sake of simplicity, let = 1 then
-
NUMERICAL EXAMPLES
Example 3.1 We consider the Cauchy problem for porous medium equation with source term, which is the simple model for a nonlinear heat propagation in reactive medium.
[(, )] = 1( + 2 + 3)(21)
= (2 ) +
Its [
] pades approximant with 1 and 1yields
(10)
[ ] = 1 ( )With the initial condition (, 0) = 1
1
(22)
(11)
To solve the system (10) by HPM, we construct the homotopy as
Replace = 1, we obtain [ ] in terms of s as follows:
[ ] = 1 ( 1 )By using the inverse Laplace transform to [ ], we obtain
0 = [ (2 ) + 0]
(12)
the exact solution:
Substituting the Eqn.(8) in to the Eqn.(14) and equating the coefficient of p, we get the following:
(, ) = 1
(23)
0: 0 0 =
Example 3.2 we consider the non linear homogeneous gas
dynamics equation
0 0 (, 0) = 1
(13)
1: 1 = (2 0) +
+ 1 (2) (1 ) = 0, 0 1, > 0
2
(24)
0 0
1 1 (, 0) = 0 (14)
2: 2 = (2 3 0 + 2 1) +
With initial condition
(, 0) =
1 0
0
(25)
1 2(, 0) = 0 (15)
If we solve the above equations 0, 1and 2, we get the following results:
We construct a homotopy as follows:
0 = [ 2 1 (2) 0]
0 = 1
2
(26)
1 = 1
(16)
(17)
Substituting the Eqn.(8) in to the Eqn.(26) and equating the powers of p in both sides, we have
0: 0 0 =
1
2
2 = 2
(18)
0 0
(, 0)
=
(27)
0
1: 1 = 0 2
-
CONCLUSION
HPM-Laplace-Pades approximants enables us to get the
2 0
1 (2) 1 (, 0) = 0
(28)
2: 2 = 1 20 1
exact solution of the presented first order non-linear partial differential equations. One can also apply this technique to other nonlinear problems.
(01)
2(, 0) = 0
(29)
REFERENCE
-
D.J.Evans, H.Bulut, A new approach to the gas dynamics equation: an application of the decomposition method,
If we solve above equations for 0, 1and 2, we get the following results:
International Journal of Computer Mathematics, 79(7), 2002, 817-822.
0
=
(30)
Comput.Methods.Appl.Mech.Engg, 178(1999), 257-262.
-
J.H.He, Homotopy perturbation method: A new non-linear analytical technique, Appl.Math.Comput. 135(2003), 73- 79.
1 =
(31)
-
J.H.He, Homotopy perturbation method with two expanding parameters, Indian J.Physics, (88), 2014, 193 196.
2
= 2 2
(32)
-
H.Jafari, C.Chun, S. Seifi, M.Saeidy, Analytical solution of non-linear Gas Dynamics Equation by Homotopy analysis method, Applications and applied mathematics: An International Journal, 4(1), 2009, 149 -154.
Substituting the Eqns.(30), (31) and (32) in to the Eqn.(9) and truncate the series solution by second order perturbation
-
Y.Keskin, G.Oturanc: Reduced Differential transform Method for partial differential equations, International Journal of Non Linear Sciences and Numerical Simulation, 10(6),2009, 741 749.
=0
(, ) = 2
(, ) = 0
+ 1
+ 2
= (1 + +
-
T.A.Nofel, Application of the Homotopy perturbation method to non linear heat conduction problems and
2) (33)
2
Taking the Laplace transform of the Eqn. (33)
[(, )] = (1 + 1 + 1 )Fractional Vander Pol Damped Nonlinear Oscillator, Journal of Applied Mathematics, 5(2014), 852-861.
-
Olusola Ezekiel Abolarin, New improved variational Homotopy perturbation method for Bratu-type problems, American journal of computational Mathematics,3 (2013), 110-113.
2 3
1
(34)
- [9]. Zaid Odibat, Saher Momani, Modified Homotopy perturbation method: Application to quadratic Riccati ifferential equation with fractional order, Chaos, solitons
For the sake of simplicity, let =
[(, )] = ( + 2 + 3)then
(35)
& fractals, 36(2008), 167-174.
Its [ ] pades approximant with 1 and 1yields
[ ] = 1 ( )1
(36)
Replace = 1, we obtain [ ] in terms of s as follows:
[ ] = 1 ( 1 )1
By using the inverse Laplace transform to [ ], we obtain
the exact solution:
(, ) = +
(37)