On μ-symmetries, μ-reductions, and μ-conservation laws of Gardner equation

Özlem Orhan; Özer Teoman

doi:10.1080/14029251.2019.1544789

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Volume 26, Issue 1, December 2018, Pages 69 - 90

On μ-symmetries, μ-reductions, and μ-conservation laws of Gardner equation

Authors

Özlem Orhan

Department of Mathematical Engineering, Istanbul Technical University, 34469 Maslak Istanbul-Turkey,orhanozlem@itu.edu.tr

Özer Teoman

Department of Civil Engineering, Istanbul Technical University, 34469 Maslak Istanbul-Turkey,tozer@itu.edu.tr

Received 4 June 2018, Accepted 29 June 2018, Available Online 6 January 2021.

DOI: 10.1080/14029251.2019.1544789 How to use a DOI?
Keywords: μ-symmetries; μ-conservation laws; μ-reductions; classification; Gardner equation
Abstract: In this study, we represent an application of the geometrical characterization of μ-prolongations of vector fields to the nonlinear partial differential Gardner equation with variable coefficients. First, μ-symmetries and the corresponding μ-symmetry classification are investigated and then μ-reduction forms of the equations are obtained. Furthermore, μ-invariant solutions are determined and μ-conservation laws of Gardner equation are studied.
Copyright: © 2019 The Authors. Published by Atlantis and Taylor & Francis
Open Access: This is an open access article distributed under the CC BY-NC 4.0 license (http://creativecommons.org/licenses/by-nc/4.0/).

1. Introduction

Symmetry group analysis is one of the most efficient methods in the analysis of differential equations and there are many studies in the literature dealing with the analysis of differential equations based on Lie symmetries, reductions and invariant solutions [1 , 4, 17–20, 22, 25–27 ]. In addition to application of Lie point symmetries to differential equations, λ-symmetry approach, which is first studied by Muriel and Romero [14, 15], plays important role for analyzing the analytical implicit solutions of ordinary differential equations (ODEs). In the literature, in order to obtain the extension of λ-symmetries for the case of partial differential equations (PDEs), it can be characterized by λ-prolongation in J⁽ⁿ⁾M, where (M,π,B) is the space B of independent variables seen as a bundle over the space B. Once this characterization is obtained, it is extended to the ordinary differential equations for the case B = ℝ and to the partial differential equations for the case B = ℝ^p, and then to the case of systems of PDEs.

Cicogna, Gaeta and Morando [4– 6] improved the λ-symmetry approach for PDEs. These symmetries are called μ-symmetries and the corresponding conservation laws for μ-symmetries are called μ-conservation laws. In this approach, for p independent variables x = (x¹,...,x^p) and q dependent variables u = (u¹,...,u^q), μ function is a horizontal one-form μ = λ_idxⁱ on the first-order jet space (J⁽¹⁾M,π,M), where μ is a compatible, that is, D_iλ_j − D_jλ_i = 0. If μ-prolongation is applied to differential equations then the determining equations are obtained for μ-symmetries and by solving these determining equations, the infinitesimals functions ξ, τ, ϕ and λ_i are determined. The application of μ-symmetry approach not only to ODEs but also to PDEs can be seen as the new application area of the symmetry group theory to differential equations.

In the literature, the Gardner equation was initially discussed by Miura in 1968 [13]. It is known that the Gardner equation is an extension of KdV equation and it introduces the identical features of the classical KdV equation, but it expands its order of availability to a larger interval of the parameters of the interior wave motion for a certain surrounding. The event of shallow-water wave is governed by Gardner equation, which is the KdV equation with dual power nonlinearity. Experimental investigations have shown that Gardner equation models deep ocean waves rather than shallow-water waves that is used by KdV equation. It is widely used in various areas of physics, such that plasma physics, fluid dynamics, quantum field theory, and it is a useful model for the description of a great variety of wave phenomena in plasma and solid state [2,3]. The μ-symmetries and μ-conservations laws of the extended KdV equation are investigated in the study [9].

In the studies [11] and [12], Johnpillai and Khalique investigated the optimal system of one-dimensional subalgebras of the Lie symmetry algebras of the classes

ut+uux+A1(t)uxxx+A4(t)u=0,(1.1)

and

ut+u2ux+A1(t)uxxx+A4(t)u=0,(1.2)

where A₁(t) and A₄(t) represent the dispersion term and the linear damping term, respectively and u(x,t) denotes the amplitude of the relevant wave mode, which is a function of two independent variables x and t indicating the space variable in the direction of wave propagation and time parameter, respectively. Later, the same authors constructed conservation laws for Eq. (1.1) for some special forms of the functions A₁(t) and A₄(t). Additionally, Vaneeva [28] examined the variable-coefficient Gardner equation

ut+A2(t)uux+A3(t)u2ux+A1(t)uxxx=0,(1.3)

where A₂(t) and A₃(t) are smooth functions satisfying the condition A₁(t).A₃(t) ≠ 0. Bruzon and Rosa studied [23] the Gardner equation of the form

ut+A2(t)unux+A3(t)u2nux+A1(t)uxxx+A4(t)u=0,(1.4)

where n is an arbitrary positive integer. In addition, the Lie point symmetries and the corresponding conservation laws of the Gardner equation with variable coefficients for n =1 are investigated in the study [24].

We propose herein a generalized variable-coefficient Gardner equation of the form

ut+A2(t)umux+A3(t)u2nux+A1(t)uxxx+A4(t)u=0,(1.5)

where m is an arbitrary positive integer. It is known that PDEs with two independent variables can be reduced to ODEs by using Lie point symmetry groups. If one obtains some solutions for the differential equations under the symmetries that leave invariant the equation itself then these solutions are called similarity solutions, which are invariant under the Lie group of transformations. In the literature, there are some studies in which exact solutions of PDEs are obtained from the similarity reductions, for example [20, 21]. For the cases of μ-symmetries, μ-reductions and μ-invariant solutions, the concept of the infinitesimal symmetry generator and the standard conservation laws should be redefined by taking account of μ-infinitesimal functions and λ_i functions [7, 8]. One of the aims of the present study is also to classify the μ-symmetries of the Gardner equation and to obtain μ-invariant solutions of the Gardner equation by using μ-symmetries and to determine μ-conservation laws.

This study is organized as follows. In section 2, we present the fundamental definitions about μ-prolongation and μ-symmetries. In section 3, we discuss some different forms of the Gardner equation and the corresponding determining equations. This section also includes different cases corresponding to different choices of coefficients. Furthermore, μ-symmetries for each different case are presented. Section 4 presents similarity reductions and some invariant solutions of a generalized variable coefficient Gardner equation. In the section 5, we examine μ-conservation laws of the Gardner equation. The last section summarizes some important results in the study.

2. Preliminaries

In this section, we introduce the concept of μ-symmetries for PDEs. Let us consider a space M = B×U with coordinates x ∈ B ≃ ℝ^p and u ∈ ℝ^q, x is an independent and u is a dependent variable. M is the total space of a linear bundle (M,π,B) over the base space B. The bundle M can be prolonged to the k-jet bundle (J⁽^k⁾M,π_k,B), with J⁽⁰⁾M ≡ M, the total space of the jet bundle is also called the jet space. Now we suppose any bundle P, the set of sections of this bundle is denoted by Γ(P) and the set of vector fields in P by χ(P). And μ = λ_idxⁱ be horizontal one-form on first-order jet space (J⁽¹⁾M,π,M) and compatible with contact structure ε on J⁽^k⁾M for k ≥ 2, i.e. dμ ∈ J(ε), where J(ε) is Cartan ideal generated by contact structure e and λ_i : J⁽¹⁾M → ℝ. μ-symmetries should satisfy the compatibility condition, that is D_iλ_j − D_jλ_i = 0, where D_i is total derivative of xⁱ. The horizontal one-form μ ∈ Λ¹(J¹M) on the vector bundle (M,π,ℝ) is the one-form μ = λ(x,u,u_x)dx, where λ(x,u,u_x) : J⁽¹⁾M → ℝ is smooth real function.

Definition 2.1 ([16]).

Let us consider x-derivatives of function u in J⁽^k⁾M. Then one can introduce a canonical contact conjecture in the jet space J⁽^k⁾M, that is, the module generated by the set of canonical contact one-forms υaj:=duja−uj,madxm.

Definition 2.2 ([7]).

Let Y be a vector field on J^kM. The vector field Y preserves the contact structure if L_Y : ε → ε.

Definition 2.3 ([7]).

A vector field X ∈ χ(M) can be written as

X=ξi(x,u)∂∂xi+ϕj(x,u)∂∂xi.(2.1)

This can be extended to a vector field X(k) in J⁽^k⁾M by requiring that it preserves the contact structure. Thus, the vector field in J⁽^k⁾M can be written

Y=X+∑n=1kΨn∂∂un.(2.2)

Definition 2.4 ([7]).

Let X = ξ∂_x +η∂_t +ϕ∂_u be a vector field on M and Y=X+∑n=1kΨn(∂/∂un) be a vector field on J^kM. Let λ: J¹M → ℝ be a smooth function. We say that Y is the λ-prolongation of X if its coefficients satisfy the λ-prolongation formula

Ψn+1=((Dx+λ)Ψn)−un+1((Dx+λ)ξ),(2.3)

for all n = 0,...,k − 1.

Definition 2.5 ([7,8]).

Let Δ be a k-th order ODE for u = u(x), u ∈ U = ℝ, and let (M = U ×B,π,B) be the corresponding variables bundle. Let the vector field Y in J^kM be the λ-prolongation of the Lie-point vector field X in M. Then we say that X is a λ-symmetry of Δ if and only if Y is tangent to the solution manifold S_Δ, that is, iff there is a smooth function Φ on J^kM such that Y (Δ) = ΦΔ.

We take λ: J¹M → ℝ, and then the λ-prolongation of a Lie-point vector field in M is a vector field in each JⁿM. We can consider λ: J^rM → ℝ, obtaining obvious generalizations of the results. In this case the λ-prolongations of X would be generalized vector fields in each JⁿM with n > 0 even if X is a Lie-point vector field. The same procedure can be applied to the μ-prolongation.

Proposition 2.1.

The vector field Y ∈ χ(J^kM), projecting to a vector field X ∈ χ(M) if and only if it preserves the contact structure in J^kM.

Theorem 2.1 ([7,8]).

Let Δ be a scalar PDEs of order k for u = u(x¹,...,x^p). Let X = ξ∂_x + η∂_t + ϕ∂_u be a vector field on M, with characteristic Q = ϕ − ξu_x − τu_t and let Y be the μ-prolongation of order k of X. If X is a μ-symmetry for Δ, then Y : ϕ_X → T ϕ_X , where ϕ_X ⊂ J^kM is the solution manifold for the system Δ_X made of Δ and E_J ≔ D_JQ = 0 for all J with |J| = 0,1,...,k − 1.

3. μ-symmetries of Gardner equation

In this section, we study μ-symmetry properties of the Gardner equations with variable coefficients. To deal with μ-symmetry analysis, the Gardner equation can be considered in different forms including a general form. For this purpose, we first, deal with the generalized variable-coefficient Gardner equation of the form

ut+A2(t)umux+A3(t)u2nux+A1(t)uxxx+A4(t)u=0,(3.1)

where n and m are non-zero integers. To determine μ-symmetries, first μ-prolongation of the vector field Y is applied to Gardner equation and then the determining equations are obtained. In order to determine μ-symmetries of PDEs, one can use the similar method as in the case for λ-symmetries of ODEs. Let us say X be a vector field on M and Y be μ-prolongation of μ = λ_idxⁱ. When the μ-prolongation of the vector field Y is applied to the differential Eq. (3.1) and then the determining equations can be obtained for μ-symmetries and the infinitesimal functions ξ, τ, ϕ, and λ_i. In addition, X = ξ∂_x +η∂_t + ϕ∂_u is a vector field and μ = λ₁dx+λ₂dt is a horizontal one-form. For λ₁ and λ₂ functions, the necessary condition to be satisfied is called the compatibility condition, which is represented by the formula D_tλ₁ = D_xλ₂. Thus, μ-prolongation of infinitesimal generator X (2.1) is written

Y=X+ψx∂ux+ψt∂ut+ψxx∂uxx+⋯+ψttt∂uttt,(3.2)

where

ψx=(Dx+λ1)ϕ−ux(Dx+λ1)ξ−ut(Dx+λ1)η,ψt=(Dt+λ2)ϕ−ux(Dt+λ2)ξ−ut(Dt+λ2)η,ψxx=(Dx+λ1)ψx−uxx(Dx+λ1)ξ−uxt(Dx+λ1)η,ψxt=(Dx+λ2)ψx−uxx(Dx+λ2)ξ−uxt(Dx+λ2)η,ψtt=(Dx+λ2)ψt−utx(Dt+λ2)ξ−utt(Dt+λ2)η,ψxxx=(Dx+λ1)ψxx−uxxx(Dx+λ1)ξ−uxxt(Dx+λ1)η,ψxxt=(Dt+λ2)ψxx−uxxx(Dt+λ2)ξ−uxxt(Dt+λ2)η,ψxtt=(Dx+λ2)ψxt−uxtx(Dx+λ2)ξ−uxtt(Dx+λ2)η,ψttt=(Dt+λ2)ψtt−uttx(Dx+λ2)ξ−uttt(Dt+λ2)η.(3.3)

Now if we suppose μ = λ_idxⁱ is horizontal 1-form and V = exp(∫ μ)X is exponential vector field, where X is a vector field given by formula (2.1) then the characteristic function is defined as Q = ϕ − u_iξⁱ. Thus, one can write

V=exp(∫λ1dx+λ2dt)X, Q=ϕ−ξux−ηut.(3.4)

If the μ-prolongation Y is acted on the Eq. (3.1) and by substituting (−A₂(t)u^mu_x −A₃(t)u²ⁿu_x − A₁(t)u_xxx − A₄(t)u) for u_t, we can use the property of functional independence of the variables u(x,t) and its derivatives and rearrange all polynomials, and separate independent functions, and equate the coefficients of various powers of the variables to zero. As a result, the following over-determined system of partial differential equations called determining equations are obtained in terms of η(x,t,u), ξ(x,t,u), ϕ(x,t,u), λ₁(x,t,u), and λ₂(x,t,u) functions

3A12(t)ηu=0, A1(t)ξuuu=0, ϕuu=0,A1(t)(−3ξu+A1(t)(3ηx(λ1)u+η(3λ1(λ1)u+2(λ1)ux)))=0,4A1(t)A3(t)(ηλ1+ηx)=0, 6n(λ1)u+u(λ1)uu=0,2u2nA3(t)(9nηx+η(9nλ1+2u(λ1)u)+umA2(t)(9mηx+η(9mλ1+4u(λ1)u)+u(4ξ(λ1)u+9λ1ξu−3ϕuu+9ξxu)))=0,6n(2n−1)ηx+η(6n(2n−1)λ1+u(6n(λ1)u)+u(λ1)uu)=0,3(m−1)mηx+η(3(m−1)mλ1+u(3mλ1)u+u(λ1)uu)=0,2uA1(t)A3(t)η3(2nA1(t)A3(t)A2′(t)η2+A2(t)(−mA1(t)A3′(t)η2=0,ηA3′(t)+2umA2(t)A3(t)(ηλ1+ηx+u2nA32(t)(ηλ1+ηx)+A3(t)(ηλ2−λ1ξ+ηt−ξx+A1(t)(3λ12ηx+3λ1ηxx+ηxxx+3ηx(λ1)uux+3ηx(λ1)x+η(λ13+4(λ1)uuxx+(λ1)uuux2+3λ1(ux(λ1)u+(λ1)x)+2ux(λ1)xu+(λ1)xx))))=0,ηA1′(t)+A1(t)(ηλ2−3λ1ξ+ηt+4umA2(t)((ηλ1+ηx)+4u2nA3(t)(ηλ1+ηx)−3ξuux−3ξx)+A12(t)(3λ12ηx+3λ1ηxx+ηxxx+3ηx(λ1)uux+3ηx(λ1)x+η(λ13+(λ1)uuxx+(λ1)uuux2+3λ1(ux(λ1)u+(λ1)x+2ux(λ1)xu+(λ1)xx))=0,4(m−5n)nA12(t)A32(t)A2′(t)−4nA1(t)A2(t)(−3mA1(t)A2′(t)A3′(t)+(m−2n)A3(t)(2A1′(t)A2′(t)+A1(t)A2″(t)))+A22(t)m(4n−5m)A12(t)A3′2(t)+(m−2n)2A32(t)(A1′2(t)−2A1(t)A1″(t)) +2m(m−2n)A1(t)A3(t)(2A1′(t)A3′(t)+A1(t)A3″(t))=0,2(m−5n)A1(t)A32(t)A2′(t)+A2(t)A3(t)((2n−m)A3(t)A1′(t)A2′(t)+A1(t)(3(m+2n)A2′(t)A3′(t)+2(m−2n)A3(t)(3nA4(t)A2′(t)−A2″(t)+A22(t)((4n−5m)A1(t)A3′2(t)+(m−2n)2A32(t)(A4(t)A1′(t)+2A1(t)A4′(t))−(m−2n)A3(t)(−A1′(t)A3′(t)+A1(t)(3mA4(t)A3′(t)−2A3″(t))))=0.(3.5)

The standard but somewhat troublesome calculations for above determining equations yield unknown functions as infinitesimal functions, namely, η, ξ, ϕ of the infinitesimal generator (2.1) of the form

ξ(x,t,u)=F(x,t),η(x,t,u)=−(A1(t)(c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt))3nm−2n(2mc2−4nc2−3mt)F(x,t))/(−2mm−2nc1(2c2(m−2n)−3mt)(2−4n3mc3(c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt))2nm(2mc2−4nc2−3mtm−2n)4n−2m3m)3m2(m−2n)+A1(t)mx(c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt))3nm−2n),(3.6)

ϕ(x,t,u)=(A1(t)(c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt))3nm−2nu(c4−2m+mA4(t)(2mc2−4nc2−3mt))F(x,t))/(m(−2mm−2nc1(2c2(m−2n)−3mt)(2−4m3mc3(c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt))2nm(2mc2−4nc2−3mtm−2n)4n−2m3m)3m2(m−2n)+A1(t)mx(c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt))3nm−2n)),

and the corresponding λ₁ and λ₂ functions, which satisfy the compatibility condition D_tλ₁ = D_xλ₂, are

λ1(x,t,u)=−(2A1(t)c1(m−2n)A2(t)1−3nm−2nA3(t)1+3m2(m−2n)Fx(x,t)−4nA1(t)A3(t)A2′(t)(F(x,t)−xFx(x,t))+2mA1(t)A2(t)A3′(t)(F(x,t)−xFx(x,t))/(2F(x,t)(A1(t)c1(m−2n)A2(t)1−3nm−2nA3(t)1+3m2(m−2n)+2nxA1(t)A3(t)A2′(t)−mxA1(t)A2(t)A3′(t))) (3.7)

and

λ2(x,t,u)=(8A1(t)2(m−5n)nxA2(t)3n(m−2n)A3(t)2F(x,t)A2′(t)2+4c1A1(t)32(m−2n)2A2(t)2A3(t)2+3m2(m−2n)Ft(x,t)+4nxA1(t)A2(t)m+nm−2nA3(t)(6mA1(t)A2′(t)A3′(t)F(x,t)−2A1(t)(m−2n)A3(t)(F(x,t)A2″(t)−A2′(t)Ft(x,t)))+2mxA1(t)A2(t)2+3nm−2n(−A1(t)(5m−4n)A3′(t)2F(x,t)−2A1(t)(m−2n)A3(t)(F(x,t)A3″(t)−A3′(t)Ft(x,t)))/(4(m−2n)A1(t)A2(t)A3(t)F(x,t)(−A1(t)c1(m−2n)A2(t)A3(t)1+3m2(m−2n)−2nxA1(t)A3(t)A2′(t)A2(t)3nm−2n+mxA1(t)A3′(t)A2(t)m+nm−2n)),(3.8)

where m ≠ 2n, F(x,t) is an arbitrary function and c₁, c₂, c₃, c₄ and c₅ are arbitrary constants. In addition, we have following differential relations among the coefficients A₁(t), A₂(t), A₃(t) and A₄(t) for the μ-invariance condition of the Eq. (3.1), which are obtained from solutions of determining equations,

4(m−5n)nA12(t)A32(t)A2′(t)−4nA1(t)A2(t)(−3mA1(t)A2′(t)A3′(t)+(m−2n)A3(t)(2A1′(t)A2′(t)+A1(t)A2″(t)))+A22(t)(m(4n−5m)A122(t)A3′2(t)+(m−2n)2A32(t)(A1′2(t)−2A1(t)A1″(t))+2m(m−2n)A1(t)A3(t)(2A1′(t)A3′(t)+A1(t)A3″(t))=0,(3.9)

and

2(m−5n)A1(t)A32(t)A2′(t)+A2(t)A3(t)((2n−m)A3(t)A1′(t)A2′(t)+A1(t)(3(m+2n)A2′(t)A3′(t)+2(m−2n)A3(t)(3nA4(t)A2′(t)−A2″(t)+A22(t)((4n−5m)A1(t)A3′2(t)+(m−2n)2A32(t)(A4(t)A1″(t)+2A1(t)A4′(t))−(m−2n)A3(t)(−A1′(t)A3′(t)+A1(t))(3mA4(t)A3′(t)−2A3″(t)))))=0.(3.10)

Therefore, it is possible to carry out a one-type of μ-symmetry classification from Eq. (3.9) and Eq. (3.10) based on the relations between coefficients A₁(t), A₂(t), A₃(t) and A₄(t) of the Gardner equation. In addition, the other type of classification is possible with respect to the relations between parameters m and n in (3.9) and (3.10). From these two equations, it is clear that five different cases can be considered to examine μ-symmetries for different choice of integer parameters m and n, which are m ≠ n, m = n, m = −2n, m = 5n, and m = (4/5)n since Eq. (3.9) and Eq. (3.10) have different forms and different solutions for A₁(t), A₂(t), A₃(t), and A₄(t) for each case. In this study, we only examine the μ-symmetry classification with respect to relations between the parameters m and n. We consider each case in order below.

CASE I: m ≠ n. From the mathematical point of view, it is not possible to determine the general solutions of A₁(t), A₂(t), A₃(t) and A₄(t) from Eqs. (3.9) and (3.10). For this reason, we consider some special chooses of the functions A₁(t), A₂(t), A₃(t) and A₄(t). In order to obtain a specific solution for (3.9) and (3.10), for example, lets choose A₁(t) = A₁, where A₁ is a constant. Under this consideration, Eq. (3.9) becomes
A12m(4n−5m)A2(t)2A3′(t)2+4nA3(t)2((m−5n)A2′(t)2−(m−2n)A2(t)A2″(t))+2mA2(t)A3(t)(6nA2′(t)A3′(t)+(m−2n)A2(t)A3″(t)))=0, (3.11)
and Eq. (3.10) is written in the form
A1(4(m−5n)A3(t)2A2′(t)2+2A2(t)A3(t)(3(m+2n)A2′(t)A3′(t)+2(m−2n)A3(t)(3nA4(t)A2′(t)−A2″(t)))+2A2(t)2(−5m+4n)A3′(t)2+2(m−2n)2A3(t)2A4′(t)−(m−2n)A3(t)(3mA4(t)A3′(t)−2A3″(t))=0.(3.12)

It is clear that from Eq. (3.11), first, the solution of function A₃(t) can be determined and then the function A₂(t) is found from the equation (3.12) as below
A3(t)=c3A2(t)2nm(c2−3mt2m−4n)4n−2m3m,A2(t)=c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt),(3.13)
where c₂, c₃, c₄ and c₅ are constants. From equations (3.6) and (3.13), the corresponding μ-infinitesimals are written in the following form
ξ(x,t,u)=F(x,t),η(x,t,u)=−(A1(c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt))3nm−2n(2mc2−4nc2−3mt)F(x,t))/(−2mm−2nc1(2c2(m−2n)−3mt)(2−4n3mc3(c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt))2nm(2mc2−4nc2−3mtm−2n)4n−2m3m)3m2(m−2n)+A1mx(c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt))3nm−2n)),ϕ(x,t,u)=(A1(c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt))3nm−2nu(c4−2m+mA5(t)(2mc2−4nc2−3mt)F(x,t))/(m(−2mm−2nc1(2c2(m−2n)−3mt)(2−4n3mc3(c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt))2nm(2mc2−4nc2−3mtm−2n)4n−2m3m)3m2(m−2n)+A1mx(c5exp(∫c4+mA4(t)(2mc2−4nc2−3mt)2mc2−4nc2−3mtdt))3nm−2n)),(3.14)
where c₁ is an arbitrary constant.
CASE II: m = n. To provide specific solutions for the last two equations, we now choose A₁(t) = A₁t^k, where A₁ and k are constants. Under this consideration, Eq. (3.9) gets
−n2t−2+2kA12(16t2A3(t)2A2′(t)2−4tA2(t)A3(t)(3tA2′(t)A3′(t)+A3(t)(2kA2′(t)+tA2″(t)))A2(t)2((−2+k)kA3(t)2+t2A3′(t)2+2tA3(t)(2kA3′(t)+tA3″(t)))=0.(3.15)

Similarly, the equation (3.10) becomes
2ntk−1A1(A2(t)A3(t)(9tA2′(t)A3′(t)+A3(t))((k−6ntA4(t))A2′(t)+2tA2″(t)))−2nt−1+kA18tA3(t)2A2′(t)2−A2(t)2(−tA3′(t)2+nA3(t)2(kA4(t)+2tA4′(t)))−A2(t)2A3(t)((k−3ntA4(t))A3′(t)+2tA3″(t))=0.(3.16)

The solution of (3) is written
A3(t)=c3A2(t)2nm(c2−3mt2m−4n)4n−2m3m,(3.17)
where c₂ and c₃ are arbitrary constants. Combining this solution (3.17) with the solution (3), the corresponding μ-infinitesimals are determined as below
η(x,t,u)=3A1(c2+tk+1)F(x,t)3c1c33tk/2A1tk+A1(k+1)tkx, ξ(x,t,u)=F(x,t),ϕ(x,t,u)=A1F(x,t)u((3c2k+(k−2)tk+1)A3(t)−3t(c2+tk+1)A3′(t))2ntA1tkA3(t)(3c1c33tk/2+(k+1)xA1tk),(3.18)
where c₁ is a constant.
CASE III: m = −2n. To consider Eqs. (3.9) and (3.10) together, the function A₁(t) can be considered in the same form with the previous case as A₁(t) = A₁t^k. Hence, Eq. (3.9) gets
−4n2t−2+2kA12(7t2A3(t)2A2′(t)2−2tA2(t)A3(t)(−3tA2′(t)A3′(t)+2A3(t)(2kA2′(t)+tA2″(t)))A2(t)2(4(−2+k)kA3(t)2+7t2A3′(t)2−4tA3(t)(2kA3′(t)+tA3″(t)))=0,(3.19)
and Eq. (3.10) reads
4nt−1+kA1(−7tA3(t)2A2′(t)2+2A2(t)A3(t)2((k−6ntA4(t)A2′(t)2tA2′(t))A2(t)2(7tA3′(t)2+8nA3(t)2(kA4(t)+2tA4′(t))−2A3(t)((k+6ntA4(t)A3′(t)2tA3′(t)))=0.(3.20)

From the solution of Eq. (3.19), the function A₂(t)
A2(t)=c3t2kA3(t)(tk+1+c2)43,(3.21)
is found, where c₂ and c₃ are arbitrary constants. If one substitutes the function A₂(t) into Eq. (3.20) and the function A₄(t) can be obtained from the solution of Eq. (3.20) in the form
A4(t)=tkc2+t1+k(c4+∫1/(2nA32(t))t−2−k(c2k(1+k)A32(t)−t2(c2+t1+k)(A3′)2(t)+tA3(t)((t1+k−c2k)A3′(t)+t(c2+t1+k)A3″(t))dt),(3.22)
where c₄ is an arbitrary constant. For this case, from solutions of equations (3.19), (3.20) and (3.6), μ-infinitesimal functions
ξ(x,t,u)=F(x,t),η(x,t,u)=3A3(t)A1tk(c2+t1+k)(c1+t1+k)4/3F(x,t)(1+k)tkx(c2+t1+k)4/3A3(t)A1tk+3c1(c2+t1+k)(A3(t)c2t2k)3/4,ϕ(x,t,u)=−A1tk(c1+t1+k)F(x,t)(−(3c2k+(k−2)t1−k)A3(t)+3t(c2+t1+k)A3′(t)2ntA3(t)((1+k)tkxA1tk+3c1(c2+t1+k)(c2t2k)3/4),(3.23)
are determined, where c₁ is a constant.
CASE IV: m = 5n. For the function A₁(t) = A₁t^k and the Eqs. (3.9) and (3.10) are converted to the following differential equations
3n2t−2+2kA12A2(t)−4tA3(t)(−5tA2′(t)A3′(t)+A3(t)(2kA2′(t)+tA2″(t)))+A2(t)(−3(−2+k)kA3(t)2−35t2A3′(t)2+10tA3(t)(2kA3′(t)+tA3″(t)))=0,(3.24)
and
6ntk−1A1A2(t)(A3(t)(7tA2′(t)A3′(t)−A3(t))((k−6ntA4(t))A2′(t)+2tA2″(t)))A2(t)(−7tA3′(t)2+3nA3(t)2(kA4(t)+2tA4′(t))+A3(t)((k−15ntA4(t))A3′(t)+2tA3″(t)))=0.(3.25)

Thus, the solution of Eq. (3.24) yields
A2(t)=t−3k/2A3(t)5/2((1+k)c2+t1+kc3)1+k,(3.26)
where c₂ and c₃ are arbitrary constants. From solution of Eq. (3.25), the function A₄(t)
A4(t)=2nc4tk+tk∫(t−2−k(c2k(1+k)2A3(t)2−t2(c2+c2k+c3t1+k)A3′(t)2/A3(t)2)dt2n(c2+c2k+c3t1+k)++tk∫(tA3(t)(−c2k(1+k)+c3t1+k)A3′(t)+(t(c2+c2k+c3t1+k)A3″(t)))/A3(t)2)dt2n(c2+c2k+c3t1+k),(3.27)
is determined. Substituting Eqs. (3.26) and (3.27) into (3.6) leads to
η(x,t,u)=3A1(c2+c2k+c3t1+k)F(x,t)A1tk(1+k)(3c1tk/2+c3xA1tk), ξ(x,t,u)=F(x,t),ϕ(x,t,u)=A1tk(c2+c2k+c3t1+k)u(x,t)F(x,t)((3c1k(1+k)+c2(k−2)tk+1)A3(t))2ntA3(t)(3c1(1+k)t3k/2(c1+c1k+c2tk+1)+A1tk(c2+c2k+c3t1+k)c2(1+k)xtk)−A1tk(c2+c2k+c3t1+k)u(x,t)F(x,t)(3t(c1+c1k+c2t1+k)A3′(t))2ntA3(t)(3c1(1+k)t3k/2(c1+c1k+c2tk+1)+A1tk(c2+c2k+c3t1+k)c2(1+k)xtk),(3.28)
where c₁ and c₄ are constants.
CASE V: m = (4/5)n. For the same function A₁(t) considered above, Eq. (3.9) becomes
−1225n2t2k−2A12A3(t)(35t2A3(t)A2′(t)2−10tA2(t)(2tA2′(t)A3′(t)+A3(t)(2kA2′(t)+tA2″(t)))+A2(t)2(3(−2+k)kA3(t)+4t(2kA3′(t)+tA3″(t))))=0,(3.29)
and the Eq. (3.10) is written
1225nt−1+kA1A3(t)(−35tA3(t)A2′(t)2+5A2(t)(7tA2′(t)A3′(t)+A3(t)((k−6ntA4(t))A2′(t)+2tA2″(t)))+A2(t)2((−5k+12ntA4(t))A3′(t)+6nA3(t)(kA4(t)+2tA4′(t))−10tA3″(t)))=0.(3.30)

Additionally, the solution of Eq. (3.29) leads to
A2(t)=c3t3k/5A3(t)2/5(t1+k+c2)2/5,(3.31)
where c₂ and c₃ are constants. By substituting A₂(t) into (3.30), the function A₄(t)
A4(t)=c4tk+tk∫(t−2−k(c2k(1+k)2A3(t)2−t2(c2+c2k+c3t1+k)A3′(t)2/2nA3(t)2)dtc2+t1+k+tk∫(tA3(t)(−c2k(1+k)+c3t1+k)A3′(t)+(t(c2+c2k+c3t1+k)A3″(t)))/2nA3(t)2)dtc2+t1+k,(3.32)
is determined. Finally, the corresponding μ-infinitesimal functions are
η(x,t,u)=3t(c2+t1+k)A3(t)F(x,t)A3(t)t3k/2((1+k)x+3c1c35/2), ξ(x,t,u)=F(x,t),ϕ(x,t,u)=tk/2u(x,t)A3(t)F(x,t)((3c2k+(k−2)tk+1)A3(t)−3t(c2+t1+k)A3′(t))2ntx(1+k)t3k/2A3(t)2+3c1c35/2t3k/2A3(t),(3.33)
where c₁ and c₄ are constants.

In addition to these cases analyzed above, it is possible to investigate the other different forms of Gardner equations, which are represented in the introduction section. Firstly, we examine Eq. (1.1) ([11]–[12]) of the form
ut+uux+A1(t)uxxx+A4(t)u=0.

For Eq. (1.1), by using the same form for A₁(t) function, the infinitesimal functions
η(x,t,u)=(c1−3tA1)F(x,t)c2−x, ξ(x,t,u)=F(x,t), ϕ(x,t,u)=2uF(x,t)(c2−x),(3.34)
are found, where c₁ and c₂ are constants. Similarly, for Eq. (1.2) of the form
ut+u2ux+A1(t)uxxx+A4(t)u=0,
the μ-infinitesimals read
η(x,t,u)=(3t−3tlog(t))F(x,t)c1−x, ξ(x,t,u)=F(x,t), ϕ(x,t,u)=(3log(t)−1)uF(x,t)2c1−x,
where c₁ is a constant. Finally, we deal with Eq. (1.3)
ut+A2(t)uux+A3(t)u2ux+A1(t)uxxx=0,
and by considering the function of form A₁(t) = 1/(a + bt), where a and b are arbitrary constants, the functions A₂(t) and A₃(t)
A2(t)=c5(3log(a+bt)−bc1)−2b+b2c1+c36ba+bt, A3(t)=c4(3log(a+bt)−bc1)−b2c1+c33ba+bt,(3.35)
are determined, where c₃, c₄, and c₅ are constants. Thus, the μ-infinitesimal functions for the equation become
η(x,t,u)=(bc1−3log(a+bt))(a+bt)F(x,t)b(c2−x), ξ(x,t,u)=F(x,t),ϕ(x,t,u)=(c3+c1b2−2b)uF(x,t)2b(c2−x),(3.36)
where c₂ is a constant.

4. μ-reduction forms and μ-invariant solutions of Gardner equation

In this section, we consider μ-reduced forms and corresponding μ-invariant solutions of Gardner equation by using the μ-symmetries, which are determined in the previous section. In the classical Lie symmetry group theory, the reduced forms of the original differential equations can be obtained by using their symmetry groups. In this manner, one can transform a PDE to a ODE after reduction if the original equation has two independent variables. In the case of μ-symmetries of PDEs the procedure is similar to the case for the Lie point symmetries of differential equations. To obtain the μ-reduced forms, we should write the characteristic equation based on the symmetry groups of the equation for different cases. As the first application to determine μ-reduced forms of the equation, we consider the case m = n. If the functions A₁(t) and A₃(t) are chosen as constants and then the functions A₂(t) and A₄(t) are determined from the related relations given in the previous section. As a result, for these infinitesimals for the case m = n, the characteristic equation

dxF(x,t)=(c1c23−A1x)dtA1(c1−3t)F(x,t)=(c1c23−A1x)duA1uF(x,t),(4.1)

is written and then the similarity variable (invariant), which is the new independent variable for the reduced forms of the original equation is obtained by the integration of the first two terms of the characteristic equation

ζ=c1c23−A1x(c1−3t)1/3,(4.2)

and the other invariant is obtained by the integration of equations of the other terms in the characteristic equation. Thus, the corresponding similarity variable becomes

u(x,t)=u˜(ζ)(c1−3t)1/3.(4.3)

Hereby, if we substitute similarity forms into the original equation, the μ-reduced equation, for example n = 1,

(1+c3)u˜(ζ)+(ζ+u˜(ζ)(c2+u˜(ζ)))u˜′(ζ)−A15/2u˜′″(ζ)=0,(4.4)

is found. Here, it is possible to determine other forms of similarity variables and invariants for other cases of the different choices of m and n.

As the second case, we take m = 5n, A₁(t) and A₃(t) are considered as constants and thus, A₂(t) and A₄(t) are determined and the infinitesimals are found. For this reason, the characteristic equation becomes

dxF(x,t)=(3c1+c3x)dt3(c2+c3t)F(x,t)=−(3c1n+c3nx)duc3uF(x,t),(4.5)

and the first invariant is

ζ=(3c1+c3x)3c2+c3t,(4.6)

for n = 1, the other invariant is

u(x,t)=u˜(ζ)3c1+c3x,(4.7)

and the corresponding μ-reduced equation reads

c4ζ2−6c33ζ−c3ζu˜2(ζ)−c3u˜5(ζ)=0.(4.8)

As the third case, we consider m = 4/5n, A₃(t) is a constant and k = −1, that is A₁(t) = A₁/t and the functions A₂(t) and A₄(t) are determined according to these choices. Hence, one can write characteristic equation for the infinitesimal functions as below

dxF(x,t)=c1c35/2dt(1+c2)F(x,t)=2nc1c35/2u(1+c2)F(x,t),(4.9)

which yields the corresponding invariants

ζ=x−c1c35/2ln(t+c2t)(1+c2) and u(x,t)=tu˜(ζ).(4.10)

For n = 1/2, the μ-reduced equation form is

u˜3(ζ)+c4u˜3(ζ)−u˜(ζ)u˜′(ζ)−u˜8/5(ζ)u˜′(ζ)+u˜2(ζ)u˜′(ζ)+A1(6u˜(ζ)u˜′(ζ)u˜″(ζ)−6u˜′3(ζ)−u˜2u˜′″(ζ))=0.(4.11)

In addition to the previous cases, it is possible to consider μ-reduced equations for other forms of the Gardner equation. For example, let’s consider Eq. (1.1) and then for the special choices of the function A₁(t), the function A₄(t) is determined and the characteristic equation becomes

dxF(x,t)=A1(c2−x)dt(c1−3A1t)F(x,t)=(c2−x)dt2uF(x,t),(4.12)

giving the related invariants such that

ζ=(c1−3A1t)1/3c2−x and u(x,t)=u˜(ζ)(c2−x)2.(4.13)

The associated μ-reduced equation for Eq. (1.1) is

24A1ζ+c3+2u˜(ζ)=0.(4.14)

Solving μ-reduced equation and substituting into (4.13) lead to the invariant solution of the form

u(x,t)=24A12t+c3(x−c2)−8c1A12(c2−x)3.(4.15)

We now examine μ-reduced equation for the Gardner equation (1.2). For the special choice of A₁(t), the function A₄(t) is determined and the characteristic equation is written

dxF(x,t)=(c2−x)dt(c1−3t)F(x,t)=duuF(x,t).(4.16)

The corresponding invariants

ζ=(c1−3t)1/3c2−x and u(x,t)=u˜(ζ)(c2−x),(4.17)

are defined and thus the μ-reduced equation for differential equation (1.2) becomes

6ζ3+c3+ζ3u˜2(ζ)=0.(4.18)

The solution of μ-reduced equation yields the μ-invariant solution of the form

u(x,t)=c3(x−c2)3−6(c1−3t)(c2−x)(c1−3t)1/2.(4.19)

Finally, for the μ-reduced equation of the Gardner equation given by Eq. (1.3), we write the characteristic equation

dxF(x,t)=b(c2−x)dt(a+bt)(bc1−3ln(a+bt))F(x,t)=2b(c2−x)dt(2b−c1b2−c3)uF(x,t),(4.20)

thus, the similarity variables are

ζ=c2−x(2tc3−3ln(2a+t))1/3 and u(x,t)=u˜(2c2−x),(4.21)

and the μ-reduced equation for Eq. (1.3) is

u˜′(ζ)(u˜′(ζ)+ζ4(2+c3−3ln(2exp2/3−1/3ζ3)))=0,(4.22)

and solving μ-reduced equation, the μ-invariant solution

u(x,t)=c4(2c2−x),(4.23)

is determined.

Remark 4.1.

It is important to mention that μ-invariant solutions obtained in this section are both solutions of the μ-reduced equations and solutions of the original differential equations.

5. Lagrangians and μ-conservation laws

In this section, we deal with the Lagrangian functions of the Gardner equation and the corresponding μ-conservation laws. It is known that μ-symmetry is defined in the following form

μ=λidxi,(5.1)

where the functions λ_i are square matrices and it is called M-functions of the dependent variable u and independent variable x. S_Δ is the solution manifold in J^rM for given equation Δ of differential equation of order r. Thus, X is μ-symmetry of the equation Δ if Y=XMr:SΔ→TSΔ.

For a function M and one can have the relation M : J^rM → ℝ. Under this relation, X is μ-symmetry of the equation Δ for the function H that H is μ-invariant under X if Y [H] = 0 and it is mentioned as the invariance of the level manifolds of H under Y . We now consider the vector fields X having ξⁱ = 0 that is Q^j = ϕ^j thus, it is represented by a standard formulation of the classical Noether’s theorem. It is clear that these assumptions simplify the procedure. For the applicability of Noether’s theorem, we need some form of variational structure in the systems. The construction of the Euler-Lagrange equations characterizes the minimizers of a variational problem.

Definition 5.1 ([10, 16]).

Let Ω ⊂ X be an open and variational problem that consists of finding maximum and minimum values of

𝔏[u]=∫ΩL(x,u(n))dx.(5.2)

The integrand L(x,u⁽ⁿ⁾) called the Lagrangian of the variational problem 𝔏, is depend on x, u and derivatives of u.

Definition 5.2 ([16]).

We suppose that f (x) is real-valued function and ▿ f (x) is the gradient of f (x). The change of gradient can be seen by

〈∇f(x),y〉=ddε|ε=0f(x+εy),(5.3)

where 〈x,y〉 is the usual inner product. For functional 𝔏[u], the gradient is called variational derivative of 𝔏.

Proposition 5.1.

Let 𝔏[u] be a variational problem. The variational derivative of 𝔏 is

δ𝔏[u]=(δ1𝔏[u],…,δq𝔏[u]).(5.4)

If u is an extremum of 𝔏[u], then

δ𝔏[u]=0.(5.5)

Theorem 5.1.

If 𝔏[u]=∫ΩL(x,u(n))dx is variational problem, then it must be a solution of the Euler-Lagrange equations

E(L)=0.(5.6)

Definition 5.3 ([16]).

Let

D=∑jPj[u]Dj, Pj∈𝒜(5.7)

is a differential operator, its adjoint is the differential operator D^* is

D*=∑jPj[u](−D)j.(5.8)

The differential operator D : 𝒜^k → 𝒜^ℓ has adjoint D^*: 𝒜^ℓ → 𝒜^k, the adjoint of the transposed entries of D. An operator D is self-adjoint if D^* = D and it is skew-adjoint if D^* = −D.

Note that, if P ∈ 𝒜^ℓ, its Frechet derivative has adjoint Dp*:𝒜l→𝒜q.

Theorem 5.2.

Let Δ is the Euler-Lagrange expression for some variational problem 𝔏 = ∫ Ldx, i.e. Δ = E(L), if and only if the Frechet derivative D_Δ is self-adjoint: DΔ*=DΔ. The function Lagrangian for Δ can be found using the formula L[u]=∫01u.Δ[λu]dλ.

Definition 5.4.

A standard conservation law is

DiPi=0,(5.9)

where Pⁱ is a p-dimensional vector and we know that μ = λ_idxⁱ is a horizontal one-form and it satisfies the compatibility condition i.e. D_iλ_j = D_jλ_i. Now, using these property we can define μ-conservation law for this μ-symmetry [4] as

(Di+λi)Pi=0,(5.10)

where Pⁱ is a M-vector and it is called μ-conserved vector.

As a result, one can obtain μ-conservation law using the following Theorem:

Theorem 5.3 ([8]).

Let X be a vector field and ℒ = L(x,u⁽ⁿ⁾) be the n-th order Lagrangian. X is a μ-symmetry for ℒ if and only if the equation has the M-vector Pⁱ and it satisfies the μ-conservation law (D_i + λ_i)Pⁱ = 0.

Using this Theorem, the M-vector Pⁱ can be found using Lagrangian. Firstly, we suppose ℒ (x,t,u,u_x,u_t) is first order Lagrangian, the vector field X = ϕ(∂/∂ u) is a μ-symmetry for ℒ . Then, we can define the M-vector Pⁱ = ϕ(∂ ℒ/∂u_i). For second-order Lagrangian ℒ and the vector field X = ϕ(∂/∂u) is a μ-symmetry for ℒ and then, the M-vector

Pi=ϕ∂ℒui+((Dj+λj)ϕ)∂ℒuij−ϕDj∂ℒuij,(5.11)

is a μ-conserved vector.

5.1. Lagrangian of Gardner equation

Now, we consider the Gardner equation given by (1.3)

Δ:ut+A2(t)uux+A3(t)u2ux+A1(t)uxxx=0,

where A₁(t), A₂(t) and A₃(t) are smooth functions satisfying the condition A₁.A₃ ≠ 0. It is a fact that the Gardner equation does not have standard Lagrangian function itself and the equation has Lagrangian if and only if its Frechet derivative is self-adjoint. However, the Frechet derivative of Gardner equation is not self-adjoint since it is of odd order. To prove this fact, let us take the following Frechet derivative of Δ

DΔ=ddε|ε=0=((ut+εDt)+A1(t)(uxxx+εDx3)+A2(t)(u+ε)(ux+εDx)+A3(t)(u2+ε)(ux+εDx)).

The simplification gives

DΔ=Dt+A1(t)Dx3+A2(t)uDx+A2(t)ux+A3(t)u2Dx+A3(t)ux,(5.12)

and then, the adjoint operator becomes

DΔ*=(−Dt)+A1(t)(−Dx)3+A2(t)u(−Dx)+A2(t)ux+A3(t)u2(−Dx)+A3(t)ux.(5.13)

From the equations (5.12) and (5.13), one can say that it is not a variational problem since it is not self-adjoint, that is DΔ*≠DΔ. Therefore, the potential form of Gardner equation having a standart Lagrangian should be considered. For this purpose, one can consider the differential substitution u = v_x to Eq. (1.3) to write

Δv:vxt+A1(t)vxxx+A2(t)vxvxx+A3(t)vx2vxx=0.(5.14)

This equation is called “the Gardner equation in potential form” having the Frechet derivative of Δ_v of the form

DΔv+Dxt+A1(t)Dx4+(A2(t)vx+A3(t)vx2)Dx2+(A2(t)vxx+2A3(t)vxvxx)Dx.(5.15)

Thus, one can see easily that the Gardner equation in potential form is self-adjoint, that is DΔ*=DΔ. By the Theorem 5.2. it has a Lagrangian of the form

L[v]=∫01v.Δv[λv]dλ=12vvxt−12A1(t)vvxxxx+13A2(t)vvxvxx+14A3(t)vvx2vxx.(5.16)

By reducing the order of Lagrangian, one can write

L[v]=−12vxvt+12A1(t)vxx2−16A2(t)vx3−112A3(t)vx4+DivP.(5.17)

Hence, the Lagrangian of equation Δ_v becomes

ℒ=−12vxvt+12A1(t)vxx2−16A2(t)vx3−112A3(t)vx4.(5.18)

5.2. μ-conservation laws of Gardner equation

In order to analyze μ-conservation laws, let us consider the vector field in the form

Y=ϕ∂v+ψx∂vx+ψt∂vt+ψxx∂vxx+ψxt∂vxt+ψtt∂vtt, (5.19)

where

ψx=(Dx+λ1)ϕ, ψt=(Dt+λ2)ϕ, ψxx=(Dx+λ1)ψx, ψxt=(Dt+λ2)ψx, ψtt=(Dt+λ2)ψt.

In order to determine the μ-conservation forms, we deal with the application of μ-prolongation of the vector field Y (5.19) to the Lagrangian of the Gardner equation in potential form (5.18) by considering following two different cases.

Case I: In the first case, the function λ_i is considered not only functions of x, t, v and but also functions of the derivatives of v, i.e the function λ_i can be written as λ_i = λ_i(x,t,v,v_x,v_t), which is the most general case. In this case, the coefficients of the μ-prolongation of the vector field Y should be reformulated by considering the dependence of λ_i functions with respect to the derivatives of the dependent function. Hence, if the μ-prolongation of the vector field Y acts on Eq. (5.18) by substituting vt=(A1(t)vxx2−A2(t)vx3/3−A3(t)vx4/6)/vx and after straight forward but rigorous calculations one can get the following determining equation
−12vx(λ2(x,t,v,vx,vt)ϕ+(A1(t)vxx2−A2(t)vx3/3−A3(t)vx4/6)ϕu/vx+ϕt)−(12A2(t)vx2+13A3(t)vx3−(A1(t)vxx2−A2(t)vx3/3−A3(t)vx4/6)/2vx)(λ1(x,t,v,vx,vt)ϕ+vxϕu+ϕx)+A1(t)vxx(vxxϕu+λ1(x,t,v,vx,vt)(vxϕu+ϕx)+(λ1(x,t,v,vx,vt)(λ1(x,t,v,vx,vt)ϕ+vxϕu+ϕx)+vxϕxu+vx(vxϕuu+ϕxu)+ϕxu+ϕ(vxt(λ1(x,t,v,vx,vt))vt+vxx(λ1(x,t,v,vx,vt))vx+vx(λ1(x,t,v,vx,vt))vx+(λ1(x,t,v,vx,vt))x))=0.(5.20)

In this equation, one can consider λ_i functions as linear in terms of v_x and v_t since the functions λ_i depend on derivatives of v function, which satisfies the compatibility condition D_tλ₁ = D_xλ₂. Then, the solution of the determining equation is
ϕ=C(x)exp(−v(x,t)−∫(h(t)+G′(t)+Kt(x,t))dt),(5.21)

λ1=vx−C′(x)C(x)+Kx(x,t), λ2=vt+h(t)+G′(t)+Kt(x,t),(5.22)
where K(x,t), C(x), h(t) and G(t) are arbitrary functions.

Therefore, the Theorem 5.3 yields μ-conservation vectors such that
P1=−C(x)6exp(−v(x,t)−∫(h(t)+G′(t)+Kt(x,t))dt)(3vt+6A1(t)vxxx+3A2(t)vx2+2A3(t)vx3)K(x,t),P2=−C(x)2exp(−v(x,t)−∫(h(t)+G′(t)+Kt(x,t))dt)vx,(5.23)
where v(x,t) = ∫u(x,t)dx. By considering Noether Theorem for μ-symmetries, one can write μ-conservation law for the Gardner equation in the following potential form
(Di+λi)Pi=(Dx+λ1)P1+(Dt+λ2)P2=C(x)exp(−v−∫(h(t)+G′(t)+Kt(x,t))dt)(vxt+A1(t)vxxxx+A2(t)vxvxx+A3(t)vx2vxx)=QE(ℒ).(5.24)

In order to write μ-conservation law for the Gardner equation in its original form (1.3) (not potential), first, the equation is written in following form
Dx(vt+A1(t)vxxx+12A2(t)vx2+13A3(t)vx3)=0,(5.25)
and then substituting u in v_x gives
(vt+A1(t)uxx+12A2(t)u2+13A3(t)u3)=R(t),(5.26)
where R(t) is an arbitrary function. Hence, one can compute μ-conserved vectors in the forms
P1=−C(x)12exp(−v(x,t)−∫(h(t)+G′(t)+Kt(x,t))dt)(6R(t)+6A1(t)uxx+3A3(t)u2+2A4(t)u3),P2=−C(x)2exp(−v(x,t)−∫(h(t)+G′(t)+Kt(x,t))dt)u.(5.27)

As a consequence, the corresponding μ-conservation law of the Gardner equation in the original form is written as
(Dx+λ1)P1+(Dt+λ2)P2=−C(x)2exp(−v(x,t)−∫(h(t)+G′(t)+Kt(x,t))dt)(ut+A3(t)uux+A4(t)u2ux+A1(t)uxxx)=QΔ.(5.28)
Case II: As a second case, we consider the case λ_i = λ_i(x,t,v) and then the solution of determining equation (5.20) yields
ϕ=S(x,t),(5.29)
where S(x,t) is an arbitrary function and it can be shown that it satisfies the condition ℒ [v] = 0. Firstly, the corresponding λ₁ and λ₂ functions
λ1=−Sx(x,t)S(x,t), λ2=−St(x,t)S(x,t),(5.30)
are determined. It is clear that λ₁ and λ₂ satisfy the compatibility condition. Then, μ-conservation vectors Pⁱ
P1=−16(3vt+6A1(t)vxxx+A2(t)3vx2+2A3(t)vx3)S(x,t), P2=−vx2S(x,t),(5.31)
are obtained and the corresponding μ-conservation law for the potential form
(Di+λi)=(Dx+λ1)P1+(Dt+λ2)P2=S(x,t)(vxt+A1(t)vxxxx+A2(t)vxvxx+A3(t)vx2vxx)),(5.32)
is found. Similar to the first case, μ-conservation vectors for the original Gardner equation is determined in the following form
P1=−112(6A1(t)uxx+3A2(t)u2+2A3(t)u3+6H(t))S(x,t), P2=−u2S(x,t),(5.33)
where H(t) is an arbitrary function. Finally, μ-conservation law of the original Gardner equation is of the form
(Dx+λ1)P1+(Dt+λ2)P2=S(x,t)(ut+A2(t)uux+A3(t)u2ux+A1(t)uxxx)=QΔ.(5.34)

Remark 5.1.

It is also important to express that the μ-conservation laws of the Gardner equations with variable coefficients obtained in this section are new. In addition, the corresponding conservation laws of the Gardner equations with variable coefficients are obtained in two different forms by using μ-symmetry approach for the first time in the literature.

6. Concluding Remarks

In this study the concept of μ-symmetry is represented to analyze μ-symmetry classification, μ-reductions, μ-invariant solutions, and μ-conservations laws of nonlinear partial differential Gardner equation with variable coefficients. The important object in this method is a horizontal one-form μ = λ_i(x,u,u_x)dx_i, which must satisfy compatibility conditions. Firstly, some important properties of μ-symmetries are presented. Then we show that the method of μ-reduction can also be interpreted in terms of the formulation of the Noether theorem when μ-symmetries are considered to find the invariant solutions of partial differential equations, which are called μ-invariant solutions. In this view, we investigate μ-symmetries for different cases of equation parameters, namely m and n, μ-reduction forms and some invariant solutions of the Gardner equations.

Furthermore, we analyze μ-conservation laws of Gardner equation. It is known that Gardner equation does not have standard Lagrangian function itself. We know that the equation has Lagrangian if and only if its Frechet derivative is self-adjoint. In addition, the Frechet derivative of the equation is not self-adjoint since it is of odd order. However, the equation in potential form is self-adjoint that is DΔ*=DΔ that this means it has a Lagrangian.

The μ-conservations laws of the Gardner equation in potential form are considered in two different cases. Firstly the new conservation law is determined by considering the dependence of λ_i functions with respect to the derivatives of the dependent function that is λ_i = λ_i(x,t,v,v_x,v_t), which is the most general case. For this case, μ-conservations laws are determined not in the potential form but also in the form of original variables. As a second case, the function λ_i is considered only functions of x, t, and v variables. In this case, we also obtain new conservation laws of the equation both in the potential form and in the form of the original variables. We show that the both conservation laws corresponding to these two cases have different forms.

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Journal: Journal of Nonlinear Mathematical Physics
Volume-Issue: 26 - 1
Pages: 69 - 90
Publication Date: 2021/01/06
ISSN (Online): 1776-0852
ISSN (Print): 1402-9251
DOI: 10.1080/14029251.2019.1544789 How to use a DOI?
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TY  - JOUR
AU  - Özlem Orhan
AU  - Özer Teoman
PY  - 2021
DA  - 2021/01/06
TI  - On μ-symmetries, μ-reductions, and μ-conservation laws of Gardner equation
JO  - Journal of Nonlinear Mathematical Physics
SP  - 69
EP  - 90
VL  - 26
IS  - 1
SN  - 1776-0852
UR  - https://doi.org/10.1080/14029251.2019.1544789
DO  - 10.1080/14029251.2019.1544789
ID  - Orhan2021
ER  -

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