This paper investigates the solitary wave solutions of the (2+1)-dimensional regularized long-wave (2DRLG) equation which is arising in the investigation of the Rossby waves in rotating flows and the drift waves in plasmas and (2+1) dimensional Davey-Stewartson (DS) equation which is governing the dynamics of weakly nonlinear modulation of a lattice wave packet in a multidimensional lattice. By using extended mapping method technique, we have shown that the 2DRLG-2DDS equations can be reduced to the elliptic-like equation. Then, the extended mapping method is used to obtain a series of solutions including the single and the combined non degenerative Jacobi elliptic function solutions and their degenerative solutions to the above mentioned class of nonlinear partial differential equations (NLPDEs).
In the recent years, seeking exact solutions of nonlinear partial differential equations (NLPDEs) is of great significance, since the nonlinear complex physical phenomena related to the NLPDEs are involved in many fields from physics (plasma physics, optical fibers, solid state physics, nonlinear optics and so on), fluid mechanics, biology, chemistry kinetics, geochemistry and engineering. As mathematical models of the phenomena, the investigation of exact solutions of NLPDEs will help one to understand the mechanism that governs these physical models or to better provide knowledge of the physical problem and possible applications. To this aim, a vast variety of powerful and direct methods for finding the exact significant solutions of the NLPDEs through it is rather difficult have been derived. Some of the most important methods are Hirota’s dependent variable transformation [
The Frobenius integrable decompositions (FIDs) and rational function transformations (RFTs) are used to construct exact solutions to NLPDEs with BTs and auto BTs [35-40]. Recently, Ma et al. [
The main aim of this paper is to find exact solitary solutions of (2+1) dimensional regularized long wave (2DRLW) and (2+1) Davey-Stewartson (DS) equations. The paper is organized as follows: This introduction is presented in Section 1. In Section 2 we give a description of the extended mapping method and we apply this method to the (2+1) regularized long wave equation and the Davey-Stewartson equation. In Section 3, some conclusions are given.
We are given a NLPDE for in the form
Introducing the similarity variable, then the function satisfies the following ordinary differential equation (ODE)
By virtue of the extended mapping method we assume that the solution of Equation (2) in the form
where in Equation (3) is a positive integer that can be determined by balancing the nonlinear term(s) with the highest derivative term in Equation (2) and a, , , and are constants to be determined. The function satisfies the nonlinear ODE
where and are constants. Substituting Equation (3) with Equation (4) into the ODE Equation (2) and setting the coefficients of the different powers of to zero yields a set of algebraic equations for, , , , and. Solving the algebraic equations by use of Maple or Mathematica, we have, , , , and expressed by. Substituting the obtained coefficients into Equation (3), then concentration formulas of travelling wave solutions of the NLPDE Equation (1) can be obtained. Selecting the values of and the corresponding JEFs from the table in Appendix and substituting them into the concentration formulas of solutions to obtain the explicit and exact JEF solutions of Equation (1). Various solutions of Equation (4) were constructed using JEFs, and these results were exploited in the design of a procedure for generating solutions of NLPDEs. The JEFs and where
is the modulus of the elliptic function, are double periodic and posses the following properties
In addition when, the functions and degenerate as and, respectively, while when, and degenerate as and 1, respectively. So, we can obtain hyperbolic function solutions and trigonometric function solutions in the limit cases when and. Some more properties of JEFs can be found in [
Let us first consider the regularized long wave equation:
have been reported in [42,43] where the coefficients β1, γ2, and are all constants. Equation (5) is related to the drift waves in plasma and the Rossby waves in rotating fluids [
where and
Integrating once with respect to ξ and setting the integration constant equal to zero, one has
Balancing with gives the leading order. So take the anastz
where, , , , , , , and are constants and need to be determined, is a solution of Equation (4). Substituting Equation (4) and Equation (8) into Equation (7) and setting the coefficients of, to zero, we get a system of nonlinear equations for, , , , , , , and. Solving this system by use of Mathematica, we obtain:
,
,
,
,
If, , this yields the exact solutions of Equation (7) as follows:
when, the solitary wave solutions of Equation (5) are obtained as follows:
We have represented this solution for a set of parameter values in
When, the triangular periodic solutions of Equation (5) are obtained as follows:
We have represented this solution for a set of parameter values in
If, , , and when, this yields the solitary solutions of Equation (5) as follows:
We have represented this solution for a set of parameter values in
If, , ,
and when, this yields the solitary solutions of Equation (5) as follows:
We have represented this solution for a set of parameter values in
If, , , and when, this yields the solitary solutions of Equation (5) as follows:
We have represented this solution for a set of parameter values in
The dimensionless form of the DSE in (2+1) dimensions, with power law nonlinearity [
Here, in Equations (19a) and (19b), and are the dependent variables while and are the independent variables. The first two of the independent variables are the spatial variables while t represents time. In Equations (19a) and (19b), is a complex valued function while is a real valued function. Also, are all constant coefficients. For solving the Equations (19a) and (19b) with the extended mapping method, using the wave variables
where both and are real functions, , , , , and are constants and is a constant determine later. Substituting Equations (20a) and (20b) into Equations (19a) and (19b), we have the following ODE for and
If we set
then Equation (21a) reduce to
Integrating Equation (21b) twice, and we take the constant of integration equal zero, we have
Substituting Equation (24) into Equation (23) yields
where
,
and
.
Balancing with gives the leading order. So take the anastz
where, , , and are constants and need to be determined, is a solution of Equation (4). Substituting Equations (4) and (27) into Equation (26) and setting the coefficients of, to zero, we get a system of nonlinear equations for, , , and. Solving this system by use of Maple, we obtain:
If, , , , we can obtain one Jacobian elliptic function solution of Equation (26) as follows:
when, the solitary solutions of Equations (25) and (24) are obtained as follows:
We have represented this solution for a set of parameter values in
If, , , this yields the solitary wave solutions of Equations (25) and (24) are obtained as follows:
We have represented this solution for a set of parameter values in
If, , ,
, this yields the solitary wave solutions of Equations (25) and (24) are obtained as follows:
We have represented this solution for a set of parameter values in
If, , , , this yields the solitary wave solutions of Equations (25) and (24) are obtained as follows:
We have represented this solution for a set of parameter values in
If, , , , this yields the solitary wave solutions of Equations (25) and (24) are obtained as follows:
We have represented this solution for a set of parameter values in
In the current article, the solitary wave solutions of the two dimensional regularized long-wave equation in plasma and rotating flows simulated by using extended mapping method, and we hope these solitary waves are helpful to understand the nonlinear phenomena described by the resonant Davey-Stewartson equation in the fields like capillarity fluids. We have presented the extended mapping method to construct more general exact solutions of NLPDEs with the help Maple and Mathematica. This method provides a powerful mathematical tool to obtain more general exact solutions of a great many NLPDEs in mathematical physics. Applying this method to the 2DRLW and DS equations and we have successfully obtained many new exact travelling wave solutions.
Through our solutions for some partial differential equations non-linear, we found lack of interest in these two methods by the specialists with the knowledge that they give an solutions more realistic than many ways, espe-
cially as they deal with the equations of non-linear coefficients fixed and transactions variable, which explain the phenomena, physical and in the various sciences. In my view this lack of interest due to the ease of the abovementioned methods.
It is a pleasure to thank the referee for critical comments on this work.
Relation between values of (,) and corresponding in ODE