Two Different Classes of Wronskian Conditions to a (3 + 1)-Dimensional Generalized Shallow Water Equation
Yaning Tang1and Pengpeng Su1
Academic Editor: G. L. Karakostas, T. Ozawa
Received04 Jun 2012
Accepted19 Jun 2012
Published07 Aug 2012
Abstract
Based on the Hirota bilinear method and Wronskian technique, two different classes of sufficient conditions consisting of linear partial differential equations system are presented, which guarantee that the Wronskian determinant is a solution to the corresponding Hirota bilinear equation of a ()-dimensional generalized shallow water equation. Our results show that the nonlinear equation possesses rich and diverse exact solutions such as rational solutions, solitons, negatons, and positons.
1. Introduction
Wronskian formulations are a common feature for soliton equations, and it is a powerful tool to construct exact solutions to the soliton equations [1โ4]. The resulting technique has been applied to many soliton equations such as the MKdV, NLS, derivative NLS, sine-Gordon, and other equations [5โ10]. Within Wronskian formulations, soliton solutions, rational solutions, positons, and negatons are usually expressed as some kind of logarithmic derivatives of Wronskian-type determinants [11โ16].
The following (3+1)-dimensional generalized shallow water equation
was investigated in different ways (see, e.g., [17, 18]). In [17], soliton-typed solutions for (1.1) were constructed by a generalized tanh algorithm with symbolic computation. In [18], the traveling wave solutions of (1.1) expressed by hyperbolic, trigonometric, and rational functions were established by the -expansion method, where satisfies a second order linear ordinary differential equation.
Under a scale transformation , (1.1) is reduced equivalently to
and the Cole-Hopf transformation
gives the corresponding Hirota bilinear equation of (1.2)
where , and are the Hirota operators [19].
As we know, in the process of employing Wronskian technique, the main difficulty lies in looking for the linear differential conditions, which the functions in the Wronskian determinant should satisfy. Moreover, the differential conditions for the Wronskian determinant solutions of many soliton equations are not unique [5, 7, 10, 12]. In this paper, we will give two different classes of linear differential conditions for the Nth order Wronskian determinant solutions (simply, Wronskian conditions) of (1.4) based on the special structure of the Hirota bilinear form (1.4). Our results will show that (1.4) has diverse Wronskian determinant solutions under different linear differential conditions and further (1.2) will have diverse exact solutions such as rational solutions, solitons, negatons, and positons.
2. The First Class of Wronskian Conditions
The Nth order Wronskian determinant was introduced firstly by Freeman and Nimmo [1, 20]:
where
Solutions determined by to (1.4) are called Wronskian determinant solutions.
In this section, we present the first class of linear differential conditions for the Wronskian determinant solutions of (1.4).
Theorem 2.1. Let a set of functions , satisfy the following linear differential conditions:
where the coefficient matrix is an arbitrary real constant matrix (see [10, 12]), is an arbitrary nonzero constant, is an arbitrary positive integer, and denotes the th order derivative of with respect to . Then the Wronskian determinant defined by (2.1) solves (1.4).
The proof of Theorem 2.1 needs the following two useful known Lemmas.
Lemma 2.2. Set to be an N-dimensional column vector, and to be a real nonzero constant. Then one has
where .
Lemma 2.3 (see [11]). Under the condition (2.3) and Lemma 2.2, the following equalities hold:
Proof of Theorem 2.1. Under the properties of the Wronskian determinant and the conditions (2.3) and (2.4), we can compute various derivatives of the Wronskian determinant with respect to the variables as follows:
Therefore, we can now compute that
Using Lemma 2.3, we can further obtain that
This last equality is just the Plรผcker relation for determinants:
where denotes an matrix, and are four N-dimensional column vectors. Therefore, we have shown that solve (1.4) under the conditions (2.3) and (2.4). Further, the corresponding solution to (1.2) is
Remarks 1. The condition (2.4) is a generalized linear differential condition which includes many different special cases. For example, when , the condition (2.4) is reduced to
When , the condition (2.4) is reduced to
When , the condition (2.4) is reduced to
Using the linear differential conditions (2.3) and (2.4) as well as the transformation (1.3), we can compute many exact solutions of (1.2) such as rational solutions, solitons, negatons, and positons. As an example, in the special case of and , the conditions (2.3) and (2.4) read
If we let the coefficient matrix of condition (2.15) has the following form (see [10โ12, 16] for details),
using the same method as that in [16], we can obtain N-soliton solutions of (1.2). For example, when , we can compute two exact 1-soliton solutions for (1.2),
with being a constant.
3. The Second Class of Wronskian Condition
In this section, we show another linear differential condition to the Wronskian determinant solutions of (1.4).
Theorem 3.1. Let a group of functions satisfy the following linear differential condition:
where is an arbitrary nonzero constant. Then the Wronskian determinant defined by (2.1) solves (1.4).
Proof. Under the properties of the Wronskian determinant and the condition (3.1), various derivatives of the Wronskian determinant with respect to the variables are obtained as follows:
Therefore, we can now compute that
then, substituting the above results into (1.4), we can further obtain that
where
From (3.5), it is easy to see that the above expression (3.4) is nothing but zero because they both satisfy the Plรผcker relation (2.10). Therefore, we have shown that also solve (1.4) under the condition (3.1). The condition (3.1) has an exponential-type function solution:
where and are free parameters and is an arbitrary natural number. In particular, we can have the following Wronskian solutions of (1.2):
where
with and being free parameters.
4. Conclusions and Remarks
In summary, we have established two different kinds of linear differential conditions for the Wronskian determinant solutions of the (3+1)-dimensional generalized shallow water equation (1.1) or equivalently (1.2). Especially, the first Wronskian conditions are generalized linear differential conditions which include many different special cases. Our results show that the nonlinear equation (1.1) carry rich and diverse Wronskian determinant solutions.
Acknowledgments
This work was supported in part by the National Science Foundation of China (under Grant nos. 11172233, 11102156, and 11002110) and Northwestern Polytechnical University Foundation for Fundamental Research (no. GBKY1034).
References
N. C. Freeman and J. J. C. Nimmo, โSoliton solutions of the Korteweg-de Vries and Kadomtsev-Petviashvili equations: the Wronskian technique,โ Physics Letters A, vol. 95, no. 1, pp. 1โ3, 1983.
X. Geng and Y. Ma, โ-soliton solution and its Wronskian form of a -dimensional nonlinear evolution equation,โ Physics Letters A, vol. 369, no. 4, pp. 285โ289, 2007.
Z. Yan, โMultiple solution profiles to the higher-dimensional Kadomtsev-Petviashvilli equations via Wronskian determinant,โ Chaos, Solitons and Fractals, vol. 33, no. 3, pp. 951โ957, 2007.
J. Wu, โ-soliton solution, generalized double Wronskian determinant solution and rational solution for a -dimensional nonlinear evolution equation,โ Physics Letters A, vol. 373, no. 1, pp. 83โ88, 2008.
J. Ji, โThe double Wronskian solutions of a non-isospectral Kadomtsev-Petviashvili equation,โ Physics Letters A, vol. 372, no. 39, pp. 6074โ6081, 2008.
Y. Zhang, Y.-N. Lv, L.-Y. Ye, and H.-Q. Zhao, โThe exact solutions to the complex KdV equation,โ Physics Letters A, vol. 367, no. 6, pp. 465โ472, 2007.
W.-X. Ma and Y. You, โSolving the Korteweg-de Vries equation by its bilinear form: Wronskian solutions,โ Transactions of the American Mathematical Society, vol. 357, no. 5, pp. 1753โ1778, 2005.
W.-X. Ma, C.-X. Li, and J. He, โA second Wronskian formulation of the Boussinesq equation,โ Nonlinear Analysis A, vol. 70, no. 12, pp. 4245โ4258, 2009.
X. Geng, โAlgebraic-geometrical solutions of some multidimensional nonlinear evolution equations,โ Journal of Physics A, vol. 36, no. 9, pp. 2289โ2303, 2003.
J. P. Wu, โA new Wronskian condition for a (
)-dimensional nonlinear evolution equation,โ Chinese Physics Letters, vol. 28, no. 5, article 050501, 2011.
Y. Tang, W.-X. Ma, W. Xu, and L. Gao, โWronskian determinant solutions of the -dimensional Jimbo-Miwa equation,โ Applied Mathematics and Computation, vol. 217, no. 21, pp. 8722โ8730, 2011.
B. Tian and Y. T. Gao, โBeyond traveling waves: a new algorithm for solving nonlinear evolution equations,โ Computer Physics Communications, vol. 95, pp. 39โ142, 1996.
J. J. C. Nimmo and N. C. Freeman, โA method of obtaining the -soliton solution of the Boussinesq equation in terms of a Wronskian,โ Physics Letters A, vol. 95, no. 1, pp. 4โ6, 1983.