A Note on the Equivalence of Methods to finding Nonclassical Determining Equations

J. Goard

doi:10.1080/14029251.2019.1613056

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Volume 26, Issue 3, May 2019, Pages 327 - 332

A Note on the Equivalence of Methods to finding Nonclassical Determining Equations

Authors

J. Goard

School of Mathematics and Applied Statistics, University of Wollongong 2522, Wollongong, NSW, Australia.,joanna@uow.edu.au

Received 6 March 2019, Accepted 29 March 2019, Available Online 6 January 2021.

DOI: 10.1080/14029251.2019.1613056 How to use a DOI?
Keywords: nonclassical symmetries; generalised conditional symmetries
Abstract: In this note we prove that the method of Bîlã and Niesen to determine nonclassical determining equations is equivalent to that of Nucci’s method with heir-equations and thus in general is equivalent to using an appropriate form of generalised conditional symmetry.
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

The focus here is on showing the equivalence of different approaches to finding the nonclassical determining equations for the partial differential equation (PDE),

ut=K(x,t,u,ux,uxx).(1.1)

In particular we address the problem posed by Hashemi and Nucci [4] who considered equations of the form (1.1): “We hope that an independent researcher will take up the task of comparing the two methods [of Bîlã and Niesen and Nucci] since we conjecture that Bîlã and Niesen’s method, and its extension, as given in [2], are equivalent to Nucci’s method.”

We consider the symmetry generator

Γ=X(x,t,u)∂∂x+T(x,t,u)∂∂t+U(x,t,u)∂∂u(1.2)

and start by considering the case when the infinitesimal T(x, t, u) ≠ 0..

2. T ≠ 0

With T ≠ 0, the corresponding invariant surface condition (ISC) is given by

Xux+Tut=U.(2.1)

In the traditional approach, nonclassical symmetries of (1.1) are defined by

Γ(2)[ut−K(x,t,u,ux,uxx)]|ut=K∩{Xux+Tut=U}(2.2)

where Γ⁽²⁾ is the second prolongation of Γ, namely,

Γ(2)=X∂∂x+T∂∂t+U∂∂u+U[x]∂∂ux+U[t]∂∂ut+U[xx]∂∂uxx,(2.3)

where

U[x]=DxU−(DxX)ux−(DxT)ut, U[t]=DtU−(DtX)ux−(DtT)ut,U[xx]=Dx(U[x])−Dx(X)uxx−Dx(T)uxt.(2.4)

Hence for nonclassical symmetries, we seek the invariance of the governing PDE subject to the PDE itself and the ISC (and its differential consequences). We note however that if f(x, t, u) is an arbitrary function, then the prolongation formula implies [f(x, t, u)Γ]⁽ⁿ⁾|_{{Xu_x+Tu_t=U}} = f(x, t, u)Γ⁽ⁿ⁾|_{{Xu_x+Tu_t=U}}. That is, by imposing the ISC we have [f(x, t, u)Γ]⁽ⁿ⁾|_{{Xu_x}+Tu_t=U} = f(x, t, u)Γ⁽ⁿ⁾. Hence if Γ is a nonclassical symmetry then f(x, t, u)Γ is also a nonclassical symmetry yielding the same invariant surface condition. This allows us to normalise any one of the nonzero coefficients of the vector field by setting it equal to one when finding nonclassical symmetries. Hence in the following, WLOG we set T = 1.

Applying (2.2) with T = 1 we get the condition

U[t]−XKx−Kt−UKu−U[x]Kux−U[xx]Kuxx=0,(2.5)

subject to u_t = K ∩ {Xu_x + u_t = U}.

We can further expand this as

Ut+Uu(U−Xux)−Xtux−Xu(U−Xux)ux−XKx−Kt−UKu−U[x]Kux−U[xx]Kuxx=0(2.6)

subject to U − Xu_x = K, where we have used u_t = U − Xu_x and the definition of U_[t].

Bîlã and Niesen [1] use the approach

Γ(2)[φ(x,t,u)/T′(x,t,u)−ξ(x,t,u)/T′(x,t,u)ux−K(x,t,u,ux,uxx)]|φ=T′−ξ/T′ux=K(2.7)

where the ISC u_t = ϕ/T′ − ξ/T′u_x has been substituted into the governing equation before taking the second prolongation. Treating ϕ and ξ as arbitrary functions of x, t, u means that (2.7) is equivalent to finding the determining equations for classical symmetries of the ordinary differential equation ϕ/T′ − ξ/T′u_x − K(x, t, u, u_x, u_xx) = 0. Then substituting ϕ = U, ξ = X, T′ = 1 leads to the determining equations for nonclassical symmetries of (1.1).

Hence Bîlã and Niesen essentially use the approach

Γ(2)[U−Xux−K(x,t,u,ux,uxx)]|U−Xux=K.(2.8)

This gives

X[Ux−Xxux−Kx]+[Ut−Xtux−Kt]+U[Uu−Xuux−Ku]−XU[x]−KuxU[x]−KuxxU[x]=0,(2.9)

subject to U − Xu_x = K, or

X[Ux−Xxux−Kx]+[Ut−Xtux−Kt]+U[Uu−Xuux−Ku]−X[Ux+Uuux−Xxux−Xuux2]−KuxU[x]−KuxxU[xx]=0,(2.10)

subject to U − Xu_x = K. The condition simplifies to

−XKx+[Ut−Xtux−Kt]+U[Uu−Xuux−Ku]−X[Uuux−Xuux2]−KuxU[x]−KuxxU[xx]=0,(2.11)

subject to U − Xu_x = K. As (2.6) and (2.11) are the same conditions they lead to the same nonclassical determining equations.

Comparison with Nucci’s method

It has been shown in [3] that Nucci’s method of heir-equations is essentially the same as the generalised conditional symmetries (GCS) method. Hence the method of finding the determining equations for nonclassical symmetries as described in [4] and [5] can be written as

Γ(σ)[ut−K(x,t,u,ux,uxx)]|σ=0∩ut=K(2.12)

where σ = K(x, t, u, u_x, u_xx) −U(x, t, u) + X(x, t, u)u_x and

Γ(σ)=σ∂∂u+(Dtσ)∂∂ut+(Dxσ)∂∂ux+⋯(2.13)

This condition is equivalent to

σt+σuK+σux(DxK)+σuxx(DxxK)=0,(2.14)

subject to σ = 0 (i.e. U − Xu_x = K) and its differential consequences with respect to x.

From (2.14) we get that the condition can be expressed as

0=Kt−Ut+Xtux+(Ku−Uu+Xuux)K+(Kux+X)DxK+KuxxDxxK=Kt−Ut+Xtux+(Ku−Uu+Xuux)(U−Xux)+(Kux+X)[Ux+Uuux−(Xx+Xuux)ux−Xuxx]+KuxxDxxK=Kt−Ut+Xtux+(Ku−Uu+Xuux)(U−Xux)+(Kux+X)[U[x]−Xuxx]+Kuxx[Dx(U[x]−Xuxx)]=Kt−Ut+Xtux+(Ku−Uu+Xuux)(U−Xux)+(Kux+X)[U[x]−Xuxx]+Kuxx[U[xx]−Xuxxx]

subject to U − Xu_x = K as D_x(U_[x]− Xu_xx) = U_[xx]+ D_x(X)u_xx − D_x(X)u_xx − Xu_xxx.

This can be further rewritten as

Kt−Ut+Xtux+(Ku−Uu+Xuux)U+(Kux+X)U[x]+KuxxU[xx]−Xux(Ku−Uu+Xuux)−Xuxx(Kux+X)−XuxxxKuxx=0,(2.15)

subject to U − Xu_x = K.

Now consider

−Xux(Ku−Uu+Xuux)−Xuxx(Kux+X)−XuxxxKuxx=−X{[Kx+uxKu+uxxKux+uxxxKuxx]−[(Ux−Xxux)+(Uuux−Xuux2)−Xuxx]}+X(Kx−Ux+Xxux)=X(Kx−Ux+Xxux)

Hence from (2.15), the condition is

Kt−Ut+Xtux+(Ku−Uu+Xuux)U+(Kux+X)U[x]+KuxxU[xx]+X(Kx−Ux+Xxux)=0,(2.16)

subject to U − Xu_x = K. Comparing (2.16) with (2.9) we see they are equivalent.

3. T= 0

When the infinitesimal symmetry T = 0 in (1.2), then as explained in the previous section, WLOG we can set X = 1. In the traditional approach we find the nonclassical determining equations using

Γ0(2)[ut−K(x,t,u,ux,uxx)]|ut=K∩ux=U(3.1)

where Γ0(2) is the second prolongation of Γ0=∂∂x+U(x,t,u)∂∂u, namely,

Γ0(2)=∂∂x+U∂∂u+U[x]∂∂ux+U[t]∂∂ut+U[xx]∂∂uxx.(3.2)

With T = 0, X = 1 we have U_[x]= D_xU, U_[t]= D_tU, U_[xx]= D_x(U_[x]).

Hence applying (3.1) we get the condition U_[t]− K_x −UK_u −U_[x]K_ux −U_[xx]K_uxx = 0, subject to u_t = K ∩ u_x = U.

We can further expand this as

U[t]−Kx−UKu−Kux[Ux+UuU]−Kuxx[Uxx+2UxuU+UuuU2+Uu(Ux+UuU)]=0,(3.3)

subject to u_t = K, where we have used u_x = U and the definition of U_[x]and U_[xx].

In [2], Bruzón and Gandarias extend the method of Bîlã and Niesen to the case T = 0. They use the approach

Γ0(2)[ut−K(x,t,u,U′/X′,Dx(U′/X′)]|ut=K(x,t,u,U′/X′,Dx(U′/X′))(3.4)

where the ISC u_x = U′(x, t, u)/X′(x, t, u) has been substituted into the governing equation before taking the second prolongation. Treating U′ and X′ as arbitrary functions of x, t, u means that (3.4) is equivalent to finding the determining equations for classical symmetries of u_t = K(x, t, u, U′/X′,D_x(U′/X′)). Then substituting U′ = U, X′ = 1, leads to the determining equations for nonclassical symmetries of (1.1).

Hence Bruzón and Gandarias essentially use the approach

Γ0(2)[ut−K(x,t,u,U,Ux+UuU)]|ut=K(x,t,u,U,Ux+UuU).(3.5)

Letting z = U_x +U_uu_x(= u_xx), this gives

U[t]−[Kx+KUUx+Kz(Uxx+UuxU)]−U[Ku+KUUu+Kz(Uxu+UuuU)]−U[x]KzUu=0(3.6)

subject to u_t = K, or

U[t]−[Kx+KUUx+Kz(Uxx+UuxU)]−U[Ku+KUUu+Kz(Uxu+UuuU)]−KzUu(Ux+UuU)=0,(3.7)

subject to u_t = K. As (3.3) and (3.7) are the same conditions they lead to the same nonclassical determining equations.

Comparison with Nucci’s method

With the infinitesimals T = 0, X = 1, Nucci’s method can be expressed as

Γ(σ)[ut−K(x,t,u,ux,uxx)]|σ=0∩ut=K(3.8)

where σ = u_x −U(x, t, u) and

Γ(σ)=σ∂∂u+(Dtσ)∂∂ut+(Dxσ)∂∂ux+⋯(3.9)

This is equivalent to

σt+σuK+σux(DxK)+σuxx(DxxK)=0,(3.10)

subject to u_t = K, σ = 0 and its differential consequences with respect to x.

This leads to −U_t −U_uK + D_xK = 0, or with z = u_xx,

0=−Ut−UuK+Kx+KuU+KU(Ux+UuU)+Kz[Uxx+2UxuU+UuuU2+Uu(Ux+UuU)]=−U[t]+Kx+KuU+KU(Ux+UuU)+Kz[Uxx+2UxuU+UuuU2+Uu(Ux+UuU)](3.11)

subject to u_t = K. Comparing (3.11) with (3.3) and (3.7) we see they all lead to the same determining equations for nonclassical symmetries.

In conclusion, we find that the method of Bîlã and Niesen when the infinitesimal T ≠ 0 and the method of Bruzón and Gandarias when T = 0 are equivalent to that of Nucci’s method for finding nonclassical symmetries of the diffusion equation (1.1) in that they lead to the same determining equations.

References

[1]N. Niesen and J. Bîlã, On a new procedure for finding nonclassical symmetries, J. Symbolic Comput, Vol. 38, 2004, pp. 1523-1533.

[2]M.S. Bruzón and M.L. Gandarias, Applying a new algorithm to derive nonclassical symmetries, Commun. Nonlinear Sci. Numer. Simul, Vol. 13, 2008, pp. 517-523.

[3]J. Goard, Generalised conditional symmetries and Nucci’s method of iterating the nonclassical symmetries method, Appl. Math. Lett, Vol. 16, 2003, pp. 481-486.

[4]M.S. Hashemi and M.C. Nucci, Nonclassical symmetries for a class of reaction-diffusion equations:the method of heir-equations, J. Nonlinear Math. Phys, Vol. 20, No. 1, 2013, pp. 44-60.

[5]M.C. Nucci, Nonclassical symmetries as special solutions of heir-equations, J. Math. Anal. Appl, Vol. 279, 2003, pp. 168-179.

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Journal: Journal of Nonlinear Mathematical Physics
Volume-Issue: 26 - 3
Pages: 327 - 332
Publication Date: 2021/01/06
ISSN (Online): 1776-0852
ISSN (Print): 1402-9251
DOI: 10.1080/14029251.2019.1613056 How to use a DOI?
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/).

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TY  - JOUR
AU  - J. Goard
PY  - 2021
DA  - 2021/01/06
TI  - A Note on the Equivalence of Methods to finding Nonclassical Determining Equations
JO  - Journal of Nonlinear Mathematical Physics
SP  - 327
EP  - 332
VL  - 26
IS  - 3
SN  - 1776-0852
UR  - https://doi.org/10.1080/14029251.2019.1613056
DO  - 10.1080/14029251.2019.1613056
ID  - Goard2021
ER  -

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