A New Method with a Different Auxiliary Equation to Obtain Solitary Wave Solutions for Nonlinear Partial Differential Equations

A newmethod with a different auxiliary equation from the Riccati equation is used for constructing exact travelling wave solutions of nonlinear partial differential equations. The main idea of this method is to take full advantage of a different auxilliary equation from the Riccati equation which has more new solutions. More new solitary solutions are obtained for the RLWBurgers and Hirota Satsuma coupled equations.


Introduction
In the recent years, remarkable progress has been made in the construction of the exact solutions for nonlinear partial differential equations, which have been a basic concern for both mathematicians and physicists [1][2][3].We do not attempt to characterize the general form of nonlinear dispersive wave equations [4,5].When an original nonlinear equation is directly calculated, the solution will preserve the actual physical characters of solutions [6].The studies in finding exact solutions to nonlinear differential equation (NPDE), when they exist, are very important for the understanding of most nonlinear physical phenomena.There are many studies which obtain explicit solutions for nonlinear differential equations.Many explicit exact methods have been introduced in literature [7][8][9][10][11][12][13][14][15][16][17][18][19][20][21].Some of them are generalized Miura transformation, Darboux transformation, Cole-Hopf transformation, Hirota's dependent variable transformation, the inverse scattering transform and the Bäcklund transformation, tanh method, sine-cosine method, Painleve method, homogeneous balance method (HB), similarity reduction method, improved tanh method and so on.
In this article, the first section presents the scope of the study as an introduction.In the second section contains analyze of a new method and balance term definition.In the third section, we will obtain wave solutions of RLW Burgers and Hirota Satsuma coupled equations by using a new method.In the last section, we implement the conclusion.

Method and Its Applications
Let us simply describe the method [22].Consider a given partial differential equation in two variables  (,   ,   ,   , . ..) = 0. ( The fact that the solutions of many nonlinear equations can be expressed as a finite series of solutions of the auxiliary equation motivates us to seek for the solutions of (1) in the form where,  = ( − ),  and  are the wave number and the wave speed respectively,  is a positive integer that can be determined by balancing the linear term of highest order with the nonlinear term in (1),  is balancing coefficient that will be defined in a new "Balance term" definition and  0 ,  1 ,  2 , . . .are parameters to be determined.Substituting (2) into (1) yields a set of algebraic equations for  0 ,  1 ,  2 , . . .because all coefficients of  have to vanish.From these  13) and ( 14). relations  0 ,  1 ,  2 , . . .can be determined.The main idea of our method is to take full advantage of the new auxiliary equation.The desired auxiliary equation presents as following where / =   and , ,  are constants.
Remark 1. Depending on the ,  and  coefficients in the (3), it could be reached only three cases.
In the following we present a new approach to the "Balance term" definition.Definition 2. When (1) is transformed with (, ) = (),  = ( − ), where  and  are real constants, we get a nonlinear ordinary differential equation for () as following   (,   ,   ,  2   , . ..) = 0. ( Let  () is the highest order derivative linear term and    ()  is the highest nonlinear term in (5) and   =  0 +  1  +  2  2 + ⋅ ⋅ ⋅ +     is the auxiliary equation that is used to solve the nonlinear partial differential equation then the "Balance term"  can be decided by the balancing the nonlinear term    () and the linear term  () with acceptances of  ≅   and   ≅   where  is integer ( ̸ = 1)and  is the balance coefficient that can be determined later.
By the balancing linear term   with nonlinear term we have the equations above and the equating If it is noticed that our new balance term  ( = 2( − 1)) is connected to .Namely our new balance term definition is connected to chosen auxiliary equation.

Application of the Method
Example 2. Let's consider RLW Burgers equation with the transform (, ) = (),  =  −  we have the following equation From the Definition 2 we have the balance term of RLW Burgers equation by using the auxiliary equation (3) for "Case 1", is equal to 4. Therefore, we may choose the following ansatz: Substituting (11) into (10) along with (3) and using Mathematica yields a system of equations w.r.t.  .Setting the coefficients of   in the obtained system of equations to zero, we can deduce the following set of algebraic polynomials with the respect unknowns  0 ,  1 ,  2 , . . .for the Case 1: From the system of (12) we have (i) (ii) From the Definition 2 we have the balance term of RLW Burgers equation by using the auxiliary equation (3) for "Case 2", is equal to −4 then we have the following system of equations From the system of ( 15) we have (i) or Example 3. Let's consider Hirota Satsuma coupled equation with the transform (, ) = (), V(, ) = V(),  =  −  we have From the Definition 2 we have the balance term of Hirota Satsuma coupled equation by using the auxiliary equation (3) for "Case 1", is equal to 4 for  and V. Therefore, we may choose the following ansatz: Substituting ( 20) into (19) along with (3) and using Mathematica yields a system of equations w.r.t.  .Setting the coefficients of   in the obtained system of equations to zero, we can deduce the following set of algebraic polynomials with the respect unknowns  0 ,  1 ,  2 , . . .for the Case 1: From the system of (21) we have (i) From the Definition 2 we have the balance term of Hirota Satsuma coupled equation by using the auxiliary equation (3) for "Case 2", is equal to −4 then we have the following system of equations

Conclusion
We have presented a new method and balance term definition and used it to solve the RLW Burgers and Hirota Satsuma coupled equations.In fact, this method is readily applicable to a large variety of nonlinear PDEs.First, all the nonlinear PDEs which can be solved by the other methods can be solved by our method.Second, we used only the special solutions of (3).If we use other solutions of (3), we can obtain more travelling wave solutions.Third it is a computerizable method, which allow us to perform complicated and tedious algebraic calculation on computer and so our balance term definition is effectively useful for any to chosen auxiliary equation.

Figure 1 :
Figure 1: Graph of the solution (, ) from left to the right for (13) and (14).

Figure 2 :
Figure 2: Graph of the solution (, ) from left to the right for (15) and (16).

Figure 4 :
Figure 4: Graph of the solutions (, ) and V(, ) corresponding to the value  0 = 1 from left to the right for (25) and (26).