Conditional Symmetry Reduction and Invariant Solutions of Nonlinear Wave Equations

Similar documents
On Reduction and Q-conditional (Nonclassical) Symmetry

A Discussion on the Different Notions of Symmetry of Differential Equations

Lie and Non-Lie Symmetries of Nonlinear Diffusion Equations with Convection Term

Nonlocal Symmetry and Generating Solutions for the Inhomogeneous Burgers Equation

On Some Exact Solutions of Nonlinear Wave Equations

A symmetry analysis of Richard s equation describing flow in porous media. Ron Wiltshire

Symmetry Reductions of (2+1) dimensional Equal Width. Wave Equation

Symmetry Properties and Exact Solutions of the Fokker-Planck Equation

Invariant and Conditionally Invariant Solutions of Magnetohydrodynamic Equations in (3 + 1) Dimensions

A Note on Nonclassical Symmetries of a Class of Nonlinear Partial Differential Equations and Compatibility

Conditional symmetries of the equations of mathematical physics

Symmetry Classification of KdV-Type Nonlinear Evolution Equations

GROUP CLASSIFICATION OF NONLINEAR SCHRÖDINGER EQUATIONS. 1 Introduction. Anatoly G. Nikitin and Roman O. Popovych

One-Dimensional Fokker Planck Equation Invariant under Four- and Six-Parametrical Group

Solitary Wave Solutions for Heat Equations

Separation of Variables and Construction of Exact Solutions of Nonlinear Wave Equations

Antireduction and exact solutions of nonlinear heat equations

New methods of reduction for ordinary differential equations

Group classification of nonlinear wave equations

A symmetry-based method for constructing nonlocally related partial differential equation systems

arxiv: v1 [math.ap] 25 Aug 2009

B.7 Lie Groups and Differential Equations

On Symmetry Reduction of Some P(1,4)-invariant Differential Equations

Lie symmetries of (2+1)-dimensional nonlinear Dirac equations

On Linear and Non-Linear Representations of the Generalized Poincaré Groups in the Class of Lie Vector Fields

Integration of Bi-Hamiltonian Systems by Using the Dressing Method

New explicit solitary wave solutions for (2 + 1)-dimensional Boussinesq equation and (3 + 1)-dimensional KP equation

ON NEW EXACT SOLUTIONS OF NONLINEAR WAVE EQUATIONS. Abstract

Exact solutions through symmetry reductions for a new integrable equation

Symmetries and reduction techniques for dissipative models

Alexei F. Cheviakov. University of Saskatchewan, Saskatoon, Canada. INPL seminar June 09, 2011

Invariant Sets and Exact Solutions to Higher-Dimensional Wave Equations

On the classification of certain curves up to projective tranformations

On Some New Classes of Separable Fokker Planck Equations

Symmetry reductions and travelling wave solutions for a new integrable equation

ANALYSIS OF A NONLINEAR SURFACE WIND WAVES MODEL VIA LIE GROUP METHOD

Periodic and Soliton Solutions for a Generalized Two-Mode KdV-Burger s Type Equation

Group Invariant Solutions of Complex Modified Korteweg-de Vries Equation

On the Linearization of Second-Order Dif ferential and Dif ference Equations

Exact Solutions for a Fifth-Order Two-Mode KdV Equation with Variable Coefficients

A Recursion Formula for the Construction of Local Conservation Laws of Differential Equations

Travelling wave solutions for a CBS equation in dimensions

On Symmetry Group Properties of the Benney Equations

Conservation Laws: Systematic Construction, Noether s Theorem, Applications, and Symbolic Computations.

The Erwin Schrodinger International Pasteurgasse 6/7. Institute for Mathematical Physics A-1090 Wien, Austria

New solutions for a generalized Benjamin-Bona-Mahony-Burgers equation

Painlevé analysis and some solutions of variable coefficient Benny equation

arxiv: v3 [math.rt] 23 Oct 2018

Note on Lie Point Symmetries of Burgers Equations

arxiv: v1 [math-ph] 25 Jul Preliminaries

Galilean invariance and the conservative difference schemes for scalar laws

Group analysis, nonlinear self-adjointness, conservation laws, and soliton solutions for the mkdv systems

New conservation laws for inviscid Burgers equation

First Integrals/Invariants & Symmetries for Autonomous Difference Equations

Extensions of Physical Theories: Quantum Mechanics with Internal Degrees of Freedom and Nonlinear Transformations

Journal of Mathematical Analysis and Applications. Complete symmetry group and nonlocal symmetries for some two-dimensional evolution equations

Potential Symmetries and Differential Forms. for Wave Dissipation Equation

Numerical Solutions to Partial Differential Equations

Symmetry classification of KdV-type nonlinear evolution equations

Group analysis of differential equations: A new type of Lie symmetries

Splitting methods with boundary corrections

Differential characteristic set algorithm for PDEs symmetry computation, classification, decision and extension

Nonclassical analysis of the nonlinear Kompaneets equation

Lecture 2: Controllability of nonlinear systems

New Formal Solutions of Davey Stewartson Equation via Combined tanh Function Method with Symmetry Method

Research Article Equivalent Lagrangians: Generalization, Transformation Maps, and Applications

Point-transformation structures on classes of differential equations

The Higher Dimensional Bateman Equation and Painlevé Analysis of Nonintegrable Wave Equations

Symmetry Methods for Differential Equations and Conservation Laws. Peter J. Olver University of Minnesota

Equivalence groupoids of classes of linear ordinary differential equations and their group classification

Constructing two-dimensional optimal system of the group invariant solutions

Department of Mathematics Luleå University of Technology, S Luleå, Sweden. Abstract

A Novel Nonlinear Evolution Equation Integrable by the Inverse Scattering Method

Superintegrability? Hidden linearity? Classical quantization? Symmetries and more symmetries!

Conservation laws for the geodesic equations of the canonical connection on Lie groups in dimensions two and three

Generalized evolutionary equations and their invariant solutions

JUST THE MATHS UNIT NUMBER ORDINARY DIFFERENTIAL EQUATIONS 1 (First order equations (A)) A.J.Hobson

Research Article New Examples of Einstein Metrics in Dimension Four

Symmetry reductions and exact solutions for the Vakhnenko equation

arxiv: v2 [nlin.si] 23 Sep 2016

First integrals and reduction of a class of nonlinear higher order ordinary differential equations

Chapter 3 Second Order Linear Equations

Approximate Similarity Reduction for Perturbed Kaup Kupershmidt Equation via Lie Symmetry Method and Direct Method

Equivalence, Invariants, and Symmetry

Ordinary Differential Equation Theory

Classification of cubics up to affine transformations

Towards Classification of Separable Pauli Equations

u = λ u 2 in Ω (1) u = 1 on Ω (2)

Lie symmetry and Mei conservation law of continuum system

Similarity Reductions of (2+1)-Dimensional Multi-component Broer Kaup System

Section 5.5 More Integration Formula (The Substitution Method) 2 Lectures. Dr. Abdulla Eid. College of Science. MATHS 101: Calculus I

Noether Symmetries and Conservation Laws For Non-Critical Kohn-Laplace Equations on Three-Dimensional Heisenberg Group

A NEW VARIABLE-COEFFICIENT BERNOULLI EQUATION-BASED SUB-EQUATION METHOD FOR SOLVING NONLINEAR DIFFERENTIAL EQUATIONS

Potential symmetry and invariant solutions of Fokker-Planck equation in. cylindrical coordinates related to magnetic field diffusion

arxiv:math-ph/ v2 9 Mar 2006

A novel difference schemes for analyzing the fractional Navier- Stokes equations

CLASSIFICATION AND PRINCIPLE OF SUPERPOSITION FOR SECOND ORDER LINEAR PDE

Final: Solutions Math 118A, Fall 2013

The Solitary Wave Solutions of Zoomeron Equation

LIE SYMMETRY, FULL SYMMETRY GROUP, AND EXACT SOLUTIONS TO THE (2+1)-DIMENSIONAL DISSIPATIVE AKNS EQUATION

Transcription:

Proceedings of Institute of Mathematics of NAS of Ukraine 2002, Vol. 43, Part 1, 229 233 Conditional Symmetry Reduction and Invariant Solutions of Nonlinear Wave Equations Ivan M. TSYFRA Institute of Geophysics of NAS of Ukraine, 32 Palladina Avenue, Kyiv, Ukraine E-mail: itsyfra@imath.kiev.ua We obtain sufficient conditions for the solution found with the help of conditional symmetry operators to be an invariant one in classical Lie sense. Several examples of nonlinear partial differential equations are considered. 1 Introduction It is well known that the symmetry reduction method is very efficient for construction of exact solutions for nonlinear partial differential equations of mathematical physics. With the help of symmetry operators one can find ansatze which reduce partial differential equation to the equation with smaller number of independent variables. Application of conditional symmetry operators essentially widens the class of ansatze reducing initial differential equation [1, 2, 3]. It turns out however that some of these ansatze result in the classical invariant solutions. It is obvious that the existence of conditional symmetry operator does not guarantee that the solution obtained with the help of corresponding ansatz is really new that it is not invariant solution in the classical Lie sense. We have proved theorem allowing us to exclude the operators that lead to the classical invariant solutions. 2 Basic theorem Let us consider some partial differential equation U(x, u, u 1,...,u k )=0, (1) where u C k ( R n, R 1), x R n,andu k denotes all partial derivatives of k-th order. Suppose that the following conditions are fulfilled. 1. Equation (1) is conditionally invariant under involutive family of operators {Q i }, i = 1,p Q i = ξ l i(x, u) + η i(x, u) u and corresponding ansatz reduces this equation to ordinary differential equation. 2. There exists the general solution of reduced equation in the following form u = f(x, C 1,...,C t ), (2) (3) where f is arbitrary smooth function of its arguments, C 1,...,C t are arbitrary real constants. The following theorem has been proved. Theorem 1. Let equation (1) be invariant under the m-dimensional Lie algebra AG m with basis elements: X j = ξ l j(x) + η j (x, u), j =1,...,m, (4) u

230 I.M. Tsyfra and conditionally invariant with respect to involutive family of operators {Q i } satisfying conditions 1, 2. If the system ξ l i u = η i(x, u) (5) x i is invariant under s-dimensional subalgebra AG s with basis elements Y a = ξ l a(x), a = 1,s, (6) of algebra AG m and s t +1, then conditionally invariant solution of equation (1) with respect to involutive family of operators {Q i } is an invariant solution in the classical Lie sense. Proof. From the theorem conditions it follows that the system of equations (1), (5) is invariant with respect to AGs algebra with basis elements Y a. Consider one parameter subgroup of transformations of space X U (variables x, u) with infinitesimal operator Y j. These transformations map any solution from (3) into solution of system (1), (5). Thus the following relations u f ( x,c 1,C 2,...,C t ) = u f ( x, C 1,...,C t), (7) where a R 1, C 1,...C t depend on C 1,...C t,a, are fulfilled in this case. Equality (7) is true for arbitrary group parameter a R 1. Considering it in the vicinity of point a = 0 we obtain ξ l a(x) f = f C 1 β j1 f C t β jt, j = 1,s, (8) where β jk = C k a at the point a = 0. As far as the mentioned reasoning is valid for arbitrary operator Y j then condition (8) is equivalent to the following system of s equations Y j f = t k=1 f C k β jk, 1 j s. (9) From system (9) it follows that there exist such real constants γ p that the the condition s γ p Y p f =0, p=1 is true since s t + 1. Therefore the solution u = f(x, C 1,...,C t ) is invariant with respect to one-parameter Lie group with infinitesimal operator Q = s γ p Y p. where Note that theorem can be generalized for infinitesimal operators of the form Y a = ξ l a(x) + η a (x, u), (10) η a (x, u) =F a (x)u +Φ a (x), (11) and F a (x) andφ a (x) are arbitrary smooth functions. p=1

Symmetry reduction and invariant Solutions of Nonlinear Wave Equations 231 3 Examples Now consider several examples. We first study nonlinear wave equation u xt =sinu. (12) We prove that equation (12) is conditionally invariant with respect to the operator ( X = u xx + 1 ) 2 tan uu2 x u. (13) We use the definition of conditional symmetry for arbitrary differential equation given in [4]. Therefore we can use the following differential consequences D x (u xt sin u) =0, D 2 x(u xt sin u) =0, D x (η) =0, (14) and u t = 2cosu u x. (15) It is easy to verify that the equality X 2 (u xt sin u) =0, where X is the extended symmetry operator of the second order, is satisfied on the manifold 2 given by relations (12), (14), (15). Thus equation (12) is conditionally invariant with respect to the Lie Bäcklund vector field (13). That is why we can reduce it by means of the ansatz which is the solution of the following equation u xx + 1 2 tan uu2 x = 0 (16) and has an implicit form H(u) =C(t)x + α(t), (17) where H(u) = du cos u. Substituting (17) into (12) we receive the reduced system in the form C 1 (t) =0, 2 C(t)α (t)+1=0. Finally by integrating this system we obtain solution of equation (12) H(u) =C 1 x 2 C 1 t + C 2. (18) Both of equations (12) and (16) are invariant with respect to three-dimensional Lie algebra with basis elements Q 1 = u x u, Q 2 = u t u, Q 3 =(tu t xu x ) u.

232 I.M. Tsyfra And also the solution depends on two constants. So, the theorem conditions are fulfilled. Thus we conclude that solution (18) is an invariant one in the classical Lie sense as a consequence of theorem. It is obvious that there exist the linear combination of operators Q 1, Q 2, Q 3 such that obtained solution is invariant under transformations generated by this operator. Now consider equation u t u xx = λ exp(u)u x + u 2 x. (19) It has been proved that equation (19) is conditionally invariant with respect to operator Q = ( u xx + u 2 ) x The corresponding ansatz has the form u =ln(f(t)x + φ(t)), (20) where f, φ are unknown functions. Substitution of (20) in (19) yields the system of two ordinary differential equations in the form f = λf 2, φ = λfφ. Having integrated this system one can obtain exact solution of equation (19) ( ) x + C1 u =ln. (21) C λt Note, that equation u xx + u 2 x =0 is invariant with respect to three-dimensional algebra with basis elements Q 1 = t, Q 2 = x, Q 3 =2t t + x x Thus according to theorem the solution (21) is an invariant one. It can be verified that solution (21) is invariant with respect to one-parameter transformation group with infinitesimal operator Q = αq 1 + βq 2 + γq 3 when α = γc 1, β = 2γCλ 1. Finally consider equation u t a(u)u xx = u(1 a(u)), (22) where a(u) is arbitrary smooth function. We have proved that equation (22) is conditionally invariant with respect to operator Q =(u xx u) The invariance surface condition leads to the following ansatz u(t, x) =φ 1 (t) exp x + φ 2 (t) exp( x), which reduces considered equation. It is easy to construct an exact solution of equation (22) using this approach in the form u = A exp(t + x)+bexp(t x), (23) where A, B are real constants. It should be noted that the maximal invariance Lie algebra of point transformations is twodimensional algebra with basis operators t, x. But solution (23) depends on two constants. Therefore the theorem conditions are not satisfied. Really it is easy to prove, that solution (23) cannot be constructed by means of Lie point group technique.

Symmetry reduction and invariant Solutions of Nonlinear Wave Equations 233 4 Conclusion Thus we obtain a sufficient condition for the solution found with the help of conditional symmetry operators to be an invariant solution in the classical sense. The theorem proved by means of infinitesimal invariance method allows us to optimize the algorithm for construction of conditional symmetry operators, a priori excluding the operators that lead to the classical invariant solutions. It is obvious that this theorem can be generalized and applicable to construction of exact solutions for partial differential equations by using the method of differential constraints, Lie Bäcklund symmetry method and the approach suggested in [5]. [1] Bluman G.W. and Cole J.D., The general similarity of the heat equation, J. Math. Mech., 1969, V.18, 1025 1042. [2] Fushchych W.I. and Tsyfra I.M., On reduction and solutions of the nonlinear wave equations with broken symmetry, J. Phys. A: Math. Gen., 1987, V.20, L45 L48. [3] Zhdanov R.Z., Tsyfra I.M. and Popovych R.O., A precise definition of reduction of partial differential equations, J. Math. Anal. Appl., 1999, V.238, 101 123. [4] Tsyfra I.M., Symmetries and reductions of partial differential equations, in Proceedings of Third International Conference Symmetry in Nonlinear Mathematical Physics (12 18 July, 1999, Kyiv), Editors A.G. Nikitin and V.M. Boyko, Kyiv, Institute of Mathematics, 2000, V.30, Part 1, 218 223. [5] Tsyfra I.M., Nonlocal ansatze for nonlinear heat and wave equations, J. Phys. A: Math. Gen., 1997, V.30, 2251 2262.

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback