Exact Solutions for the KdV Equation with Forcing Term by the Generalized tanh-coth Method and the (G/G)-Expansion Method

An application of the generalized tanh-coth method and the (G/G)-expansion method to search for exact solutions of nonlinear partial differential equations is analyzed. These methods are used for the KdV equation with forcing term. The generalized tanhcoth method and the (G/G)-expansion method were used to construct periodic wave and solitary wave solutions of nonlinear evolution equations. It is shown that the generalized tanh-cothmethod and the (G/G)-expansionmethod, with the help of symbolic computation, provide a straightforward and powerful mathematical tool for solving nonlinear problems.


Introduction
Nonlinear phenomena play a fundamental role in applied mathematics and physics.Recently, the study of nonlinear partial differential equations in modelling physical phenomena has become an important tool.The investigation of the travelling wave solutions plays an important role in nonlinear sciences.A variety of powerful methods have been presented, such as the inverse scattering transform [1], Hirota's bilinear method [2], sine-cosine method [3], homotopy perturbation method [4], homotopy analysis method [5,6], variational iteration method [7,8], tanh-function method [9], Bäcklund transformation [10], Exp-function method [11][12][13][14][15][16], tanhcoth method [17][18][19][20], (  /)-expansion method [21][22][23], Laplace Adomian decomposition method [24], and differential transform method [25].Here, we use an effective method for constructing a range of exact solutions for following nonlinear partial differential equations that in this paper we developed solutions as well.The standard tanh method is well-known analytical method which is first presented by Malfliet's [26] and developed in [26,27].In this paper, we explain method which is called the generalized tanh-coth method to look for travelling wave solutions of nonlinear evolution equations.The KdV equation with forcing term has been investigated by Zhang [28] is in the form where () is an external forcing function varying with time ,  and  are constants.Our aim of this paper is to obtain analytical solutions of the KdV equation with forcing term and to determine the accuracy of the aforementioned methods in solving these kinds of problems.Symmetries of differential equations are one of the most important concepts in theory of differential equations and physics.One of the most prominent equations is KdV (Kortwege-de Vries) equation with application in shallow water theory.There are diverse methods for finding symmetries of differential equations.One of the most important ones is Lie method.
A symmetry is a mapping of one mathematical object into itself or into another mathematical object that preserves some property of the object.

Lie Group Symmetries.
A symmetry is a mapping of one mathematical object into itself or into another mathematical object that preserves some property of the object.The easiest 2 ISRN Applied Mathematics symmetries to see are the discrete symmetries of geometrical objects, such as the rotational symmetries of the objects.Note that the sphere in the middle is invariant under a continuous group of rotational symmetries, not just a discrete group.We have been speaking implicitly about groups of transformations of families of curves (, ) =  in the plane.Let x = (, ) and X = (, ) be points in the Euclidean plane, and for  in R, let   : x  → (x, ) = X be a transformation, depending on the parameter  that takes points x to points X. Usually, we would give a rule (, ]) defining the composition of two parameters  and ], but we can always reparameterize the group, so that the composition is additive; that is, ( 1 ,  2 ) =  1 +  2 .With this parameterization, the identity element  0 becomes  0 = 0. We say the set of transformations   is a (additive) transformation group  if the following conditions are satisfied: (1)   is one-to-one and onto; (2) (3)   =  (i.e., (x, 0) = x); (4) for each  1 there exists a unique If, in addition to these four group properties,  is infinitely differentiable with respect to  and analytic with respect to , we say that  is a one-parameter Lie group (or a Lie point transformation) [29].A point transformation maps points in the Euclidean plane into other points in the plane.There are more general transformations, such as contact transformations and Lie-Bäcklund transformations.The paper is organized as follows.In Sections 2 and 3, we briefly give the steps of the methods and apply the methods to solve the nonlinear partial differential equations.In Section 4, we examine KdV equation with forcing term using the before sections of methods.Also a conclusion is given in Section 5. Finally some references are given at the end of this paper.

Basic Idea of the (𝐺 󸀠 /𝐺)-Expansion Method
Another powerful analytical method is called (  /)expansion method; we give the detailed description of method which is first presented by Wang et al. [30].
Step 2. We seek its solutions in the more general polynomial form as follows: where () satisfies the second order LODE in the form where  0 ,   ( = 1, 2, . . ., ), , and  are constants to be determined later,   = 0, but the degree of which is generally equal to or less than −1, and the positive integer  can be determined by considering the homogeneous balance between the highest order derivatives and nonlinear terms appearing in (3).
Step 4. Solving the algebraic equations in Step 3 and then substituting   , . . .,   ,  and general solutions of ( 5) into (4), we can obtain a series of fundamental solutions of (2) depending of the solution () of (5).

Basic Idea of the Generalized tanh-coth Method
We now describe the generalized tanh-coth method for the given partial differential equations.We give the detailed description of method which to use this method, we take following steps.
Step 1.For a given NLPDE with independent variables  = (, , , ) and dependent variable , we consider a general form of nonlinear equation which can be converted to on ODE at which transformation  =  +  −  is wave variable.Also,  is constant to be determined later.
Step 2. We introduce the Riccati equation as follows: that leads to the change of derivatives which admits the use of a finite series of functions of the form where   ( = 0, 2, . . ., ),   ( = 1, 2, . . ., ), , , and  are constants to be determined later.But the positive integer  can be determined by considering the homogeneous balance between the highest order derivatives and nonlinear terms appearing in (7).If  is not an integer, then a transformation formula should be used to overcome this difficulty.For aforementioned method, expansion (10) reduces to the standard tanh method [26] for   = 0, 1 ≤  ≤ .
Case 1.For each , , and  ̸ = 0, (8) has the following solution: or or or where  is constant.

The KdV Equation with Forcing Term
Case I (application of the (  /)-expansion method).In this section, we employ the KdV equation with forcing term by using the (  /)-expansion method as follows: we suppose that and then (21) reduces to Using the transformation as follows where  is a constant and () is a function of  to be determined later, ( 23) is carried to ODE where prime denotes the differential with respect to .In order to determine value of , we balance the linear term of the highest order   with the highest order nonlinear term ; in (25), we have where we conclude and we find  = 2.We can suppose that the solution of ( 21) is of the form and therefore Substituting ( 28) and ( 29) and by using the well-known software Maple, we obtain the system of following results: or or where  and  are arbitrary constants.Substituting (30)-(32) into expression (28), can be written as or or Substituting the general solutions of ( 5) into (33)-(35), we have three types of exact solutions of (21) as follows.
Case II (application of the generalized tanh-coth method).We now employ the KdV equation with forcing term by using the generalized tanh-coth method as follows: We suppose that and then (21) reduces to Using the transformation as follows where  is a constant and () is a function of  to be determined later, ( 23) is carried to a ODE where prime denotes the differential with respect to .

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By the manipulation as explained in the previous section, we have the following.

Conclusion
In this paper, we obtained exact solutions for the KdV equation with forcing term by using the generalized tanhcoth and (  /)-expansion methods.Generalized tanhcoth and (  /)-expansion methods are useful methods for finding travelling wave solutions of nonlinear evolution equations.These methods have been successfully applied to obtain some new solitary wave and periodic wave solutions to the KdV equation with forcing term.Both generalized tanh-coth method and (  /)-expansion method are more powerful in searching for exact solutions of NLPDEs.Some of these results are in agreement with the results reported in the literature.Comparing our results and Zhang's [28] results, then it can be seen that the results are the same.Also, new results are formally developed in this paper.It can be concluded that this method is a very powerful and efficient technique in finding exact solutions for wide classes of problems.