ZHANG Ying-yuan, LIU Xi-qiang, WANG Gang-wei
NONCLASSICAL LIE POINT SYMMETRY AND EXACT SOLUTIONS OF THE (2+1)-DIMENSIONAL NONLINEAR EVOLUTION EQUATION
*ZHANG Ying-yuan, LIU Xi-qiang, WANG Gang-wei
(School of Mathematical Sciences, Liaocheng University, Liaocheng, Shandong 252059, China)
Employing the compatibility method and nonclassical Lie group method, we derive the nonclassical Lie point symmetry of the (2+1)-dimensional nonlinear evolution equation. Nonclassical similarity reductions of the nonlinear evolution equation are obtained by solving the corresponding characteristic equations associated with nonclassical symmetry equations. Some new exact solutions to this equation are presented.
Nonlinear evolution equation; nonclassical Lie point symmetry; similarity reductions; exact solutions
In this paper, combining the compatibility method[1-3] and nonclassical Lie group approach[4,5], we consider the (2+1)-dimensional nonlinear evolution equation
The paper is organized as follows. In section 2, based on some results relating to the symmetry, the compatibility method and nonclassical Lie group approach are applied to the nonlinear evolution equation to get the nonclassical symmetry. In section 3, we use the nonclassical symmetry to get nonclassical similarity reductions of the nonlinear evolution equation. By solving the reduction equations, we get varieties of new exact solutions to the nonlinear evolution equation and generalize the corresponding results in Refs[6,8,9]. The last section is a short summary and discussion.
The basic idea of the compatibility method is to seek the nonclassical symmetry of a given NPDE such as Eq.(2) in the form
Similarly, we can also find the nonclassical symmetry of the Eq.(2) by the nonclassical Lie group method.The constraint condition is
(8)
The vector field (8) is a nonclassical symmetry of (2) if
Solving the determining equations, we can get the nonclassical Lie point symmetry of Eq.(2)
Remark 1 To the best our knowledge, thenonclassical Lie point symmetry is completely new and has not been studied yet.
Having determined the nonclassical symmetry (15) of the nonlinear evolution equation, nonclassical similarity variables can also be found by solving the corresponding characteristic equations
(16)
For different possibilities, we determine four independent similarity reductions of the Eq.(2) by solving Eq.(16).
Substituting Eq.(17) into Eq.(2), one can get
(18)
Therefore,Eq.(2) has the following form solution
In addition,assuming Eq. (18) has the following solution
In this section, we will consider the exact analytic solutions to the reduced equations by using the power series method. we assume that the solutions of Eq.(22) can be expressed in the form
Substituting Eq.(23) into Eq.(22), we get
Hence, the power series solution of Eq.(22) can be written as following
Combining Eq.(17) and (27), respectively, then the new exact solution of the. Eq. (2) is expressed as
Remark 2 The exact solution of the rest of Eq.(2) and the solution in the approximate form can be written in terms of the above computation. The details are omitted here.
(31)
Solving Eq.(32), we can get the following solutions of the Eq.(2)
Substituting Eq.(33) into Eq.(2),one can get the reduction of Eq.(2) as follows
In order to obtain the exact solutions of Eq.(34),using the Lie point transformation group further reduce to the Eq.(34).
The corresponding symmetry is
Then we can write the corresponding characteristic equations
Solving (41), we can get the following solutions of the JM equation (2)
Eq.(43) can be further simplified to
Remark 3 Allthe solutions presented in this paper for Eq.(2) have been verified by Maple software.
By applying the compatibility method and nonclassical Lie group method to the nonlinear evolution equation, we get the nonclassical Lie point symmetry of the Eq.(2). Using the obtained symmety, we find three nonclassical similarity reductions of the nonlinear evolution equation. On this basis, new cases of Eq.(2) have been derived by using the Lie point transformation group further reduction to the reduced equation. Some new exact solutions of the nonlinear evolution equation have been found by solving the reduction equations.
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(2+1)维非线性发展方程的非经典李点对称和精确解
*张颖元,刘希强,王岗伟
(聊城大学数学科学学院,山东,聊城 252059)
应用相容性方法和非经典李群方法,得到了(2+1)维非线性发展方程的非经典李点对称。通过求解非经典对称方程的相应的特征方程组得到了非线性发展方程的非经典相似约化。进而得到了非线性发展方程的新的精确解。
非线性发展方程;非经典李点对称;相似约化;精确解
1674-8085(2013)02-0013-07
O641
A
10.3969/J.issn.1674-8085.2013.02.003
O641
A
10.3969/j.issn.1674-8085.2013.02.003
2012-08-27
2012-11-08
Supported by National Natural Science Foundation of China and China Academy of Engineering Physics (NSAF:11076015).
*Zhang Ying-yuan(1986-), Female; Jinan Shandong; Master; research direction: the Solution of Nonlinear Evolution Equations (E-mail:zhangyingyuanok@126.com);
Liu Xi-qiang(1957-), Male; Heze Shandong;Doctor; Professor; research direction: the System of Nonlinear Evolution Equations(E-mail:liuxiq@sina.com);
Wang Gang-wei(1982-), Male; Xingtai Hebei; Master; research direction: the Solution of Nonlinear Evolution Equations (E-mail:pukai1121@163.com).