## Abstract

A simple local proof of Noether's Second Theorem is given. This proof immediately leads to a generalization of the theorem, yielding conservation laws and/or explicit relationships between the Euler–Lagrange equations of any variational problem whose symmetries depend on a set of free or partly constrained functions. Our approach extends further to deal with finite-difference systems. The results are easy to apply; several well-known continuous and discrete systems are used as illustrations.

## 1. Introduction

Variational methods are endemic in physics and engineering. Commonly, physical symmetries are built into the Lagrangian; these correspond to conservation laws via Noether's Theorem. In classical mechanics, for instance, invariance under translation in time is associated with conservation of energy, invariance under rotations in the base space yields conservation of angular momentum and so on. Noether's Theorem applies only to systems of Euler–Lagrange equations that are in Kovalevskaya form (see Olver 1993 for details). For other Euler–Lagrange systems, each non-trivial variational symmetry still yields a conservation law, but there is no guarantee that it will be non-trivial.

It is still not widely known that Noether's famous paper on variational problems (Noether 1918) includes a second theorem, which applies to variational symmetries that depend on arbitrary locally smooth functions of all of the independent variables. (Henceforth, we restrict attention to functions that are locally smooth in each continuous variable.) Noether's Second Theorem states that such symmetries exist if and only if there exist differential relations between the Euler–Lagrange equations. In this case, the Lie algebra of variational symmetries is infinite dimensional, and the Euler–Lagrange equations are not in Kovalevskaya form. Brading (2002) gives an interesting and accessible history of the mathematics and physics of Noether's two theorems and Weyl's gauge symmetries. Brading observes that Noether's Second Theorem has received scant attention in the physics literature, despite its importance for equations that have gauge symmetries. For a complete history of Noether's two theorems on variational symmetries, including some generalizations, see Kosmann-Schwarzbach (2010).

Noether's Theorem deals primarily with finite-dimensional Lie algebras of variational symmetry generators, whereas Noether's Second Theorem addresses the infinite-dimensional case when generators depend on arbitrary functions of *all* independent variables. However, there is an intermediate case that occurs commonly: generators may depend on functions that satisfy some constraints. For instance, the variational problem
for the one-dimensional wave equation is invariant under Lie point transformations whose characteristic is of the form , where is an arbitrary function. Therefore, the Lie algebra of variational symmetry generators is infinite dimensional. However, the differential constraint
applies; there are no generators that depend on an unconstrained arbitrary function `g`(*x*,*t*). Rosenhaus (2002) examines this type of problem from the global viewpoint, determining which spatial boundary conditions are necessary for the existence of integral quantities that are conserved in time. However, the effect of constraints on local conservation laws has remained an open problem until now.

Some important variational problems have variational symmetry generators that depend on several arbitrary functions that are linked by constraints. Noether's Second Theorem has not yet been generalized to deal with this type of problem.

A discrete variational problem may be a model of a discrete process, or it may be a discretization of a continuous variational problem. Either way, discrete analogues of Noether's two theorems are important. Noether's Theorem for finite-difference variational problems has now been well studied (e.g. Dorodnitsyn 2001, 2011; Hickman & Hereman 2003; Hydon & Mansfield 2004). If a discretization preserves a variational symmetry, the discrete version of Noether's Theorem guarantees that the corresponding conservation law is also preserved.

Christiansen & Halvorsen (2011) have constructed a gauge symmetry-preserving discretization of the Maxwell–Klein–Gordon equations for a charged particle in an electromagnetic field. They used the discrete analogue of Noether's Theorem to obtain a linear relationship between the discrete Euler–Lagrange equations; this was viewed (correctly) as the satisfaction of a physically important constraint. So there is evidently a need for a discrete analogue of Noether's Second Theorem.

The current paper has three purposes. First, we give a simple local proof of Noether's Second Theorem for a single arbitrary function and extend this to deal with variational symmetries that depend on several arbitrary functions. Then, we show what happens locally when the arbitrary functions are constrained in some way. Finally, we transfer these ideas to discrete variational problems. Some well-known systems are used to illustrate the application of our results.

## 2. Symmetries of Lagrangians: the continuous case

We begin by summarizing a few key facts about variational symmetries (for details, see Olver 1993). We work locally, using independent variables **x**=(*x*^{1},…,*x*^{p}) and dependent variables **u**=(*u*^{1},…,*u*^{q}). Derivatives of each *u*^{α} are written in the form , where **J**=(*j*^{1},…,*j*^{p}) is a multi-index; here, each *j*^{i} is a non-negative integer that denotes the number of derivatives with respect to *x*^{i}, and so . The *total derivative* with respect to *x*^{i} is the operator
and we shall use the following shorthand:
Here, **†** denotes the formal adjoint with respect to the *L*^{2} inner product. Henceforth, we adopt the Einstein summation convention to avoid a plethora of summation symbols. Consider the action
where [**u**] in the integrand is shorthand for **u** and finitely many of its derivatives. The Euler–Lagrange equations are obtained by varying each *u*^{α} and integrating by parts:
2.1
Here, the Euler operator **E**_{α}, which corresponds to variations in *u*^{α}, is defined by
Following Olver, we have assumed that variations are restricted to ensure that there are no contributions from the boundary of the domain. With this formal approach, two Lagrangians *L* and *L*′ lead to the same set of Euler–Lagrange equations,
2.2
if and only if *L*−*L*′ is a total divergence.

Typically, the set of all generalized (or Lie–Bäcklund) symmetries of the Euler–Lagrange equations (2.2) is not a group. However, just as for point symmetries, one can find infinitesimal generators (in evolutionary form, prolonged to all orders),
by solving the linearized symmetry condition,
The solution is a *q*-tuple **Q( x,[u])**=(

*Q*

^{1},…,

*Q*

^{q}), which is called the characteristic of the symmetries generated by

*X*. The set of characteristics of all generalized symmetries of the Euler–Lagrange equations (2.2) is a Lie algebra, whose Lie bracket is 2.3

Variational symmetries (in the broadest sense) are generalized symmetries whose infinitesimal generators satisfy the additional condition
2.4
for some functions . This condition ensures that the variational problem is invariant under such symmetries. The set of characteristics of all variational symmetries is a Lie algebra with the Lie bracket (2.3). Integrating equation (2.4) by parts yields an expression of the form
2.5
Consequently, each variational symmetry characteristic **Q** yields a conservation law
2.6
This is the local version of Noether's first (and best-known) theorem on variational symmetries.

## 3. A local approach to Noether's Second Theorem

Olver (1993) states and proves Noether's Second Theorem in the following form (using our notation).

### Theorem 3.1

*The variational problem (2.1) admits an infinite-dimensional group of variational symmetries whose characteristics depend on an arbitrary function* *(and its derivatives) if and only if there exist differential operators* *not all zero, such that*
3.1
*for all* **x**, **u**.

The theorem as stated is restricted to variational problems whose variational symmetries *do* form a group; such problems are uncommon. However, if the ‘group of variational symmetries’ is replaced by ‘Lie algebra of variational symmetry generators’, the theorem applies to all variational problems (2.1). We shall use the more general wording henceforth. This is purely for the sake of generality; the Lie algebra structure is not used in either of Noether's theorems on variational symmetries.

The ‘if’ part of Olver's proof is straightforward. Multiply equation (3.1) by an arbitrary function `g`(**x**) and integrate by parts to get an expression of the form (2.5), where
Then, reverse the steps that lead from equation (2.4) to equation (2.5) to show that **Q** is the characteristic of a variational symmetry for each `g`(**x**). Consequently, if there are no characteristics of variational symmetries that depend on a completely arbitrary function of **x**, no relation of the form (3.1) exists.

The ‘only if’ part of the proof is quite long, so we do not reproduce it here. Instead, we use the following constructive proof, which is much simpler. The key is to regard `g` as an additional dependent variable and to apply the Euler–Lagrange operator **E**_{g} to equation (2.5), giving
3.2
This is the required differential relation between the Euler–Lagrange equations. Explicitly, it amounts to
3.3
If **Q** is linear in and its derivatives, this relation is independent of `g`. Otherwise, one can linearize **Q** by taking its Fréchet derivative with respect to `g`, as explained by Olver; we discuss an alternative approach later in this section. Typically, the characteristic is independent of high-order derivatives of `g` and so equation (3.3) is easy to determine; the following example illustrates this.

(Note: in each example we use whatever notation is standard, so that readers can see the results in a familiar form, without having to translate from the notation that we use for the general theory.)

### Example 3.1

The interaction of a scalar particle of mass *m* and charge *e* with an electromagnetic field has a variational formulation with well-known gauge symmetries. The independent variables are the standard flat space–time coordinates **x**=(*x*^{0},*x*^{1},*x*^{2},*x*^{3}), where *x*^{0} denotes time. The dependent variables are the complex-valued scalar *ψ* (which is the wave function for the particle), its complex conjugate *ψ** and the real-valued electromagnetic four-potential *A*^{μ}, *μ*=0,1,2,3; indices are raised and lowered using the metric *η*=diag{−1,1,1,1}. The Lagrangian is
3.4
where
Therefore, the Euler–Lagrange equations are
where **E**_{σ} is obtained by varying *A*^{σ}. The variational symmetries include the gauge symmetries
where *λ* is an arbitrary real-valued function of **x**; the Lagrangian *L* is invariant under these transformations, so *XL*=0. The characteristics of the gauge symmetries have components
where `g` is an arbitrary real-valued function of **x**. Consequently,
and so Noether's Second Theorem yields the differential relation

Our proof of the ‘only if’ part of Noether's Second Theorem is essentially a local version of Noether's original proof (see Noether 1918). Like Noether's proof, it extends immediately to variational symmetries whose characteristics depend on *R* independent arbitrary functions and their derivatives. This gives *R* differential relations between the Euler–Lagrange equations,
3.5

A useful observation is that this set of relations is invariant under any locally invertible change of the arbitrary functions. Suppose that each `g`^{r} is a locally invertible function of a new set of arbitrary functions `h`^{ρ}, *ρ*=1,…,*R*. Then, the identity
3.6
shows that the set of relations
is obtained by taking an invertible linear combination of the original relations (3.5). So, if there exists a locally invertible change of variables such that **Q** is linear in , equation (3.5) is equivalent to a set of relations that are independent of any arbitrary functions.

It is convenient to regard equation (3.5) as ‘new’ Euler–Lagrange equations that arise when ** g** is varied in the functional
3.7
where
3.8
To prove that the relations (3.5) are independent, suppose that the converse is true; then there exist differential operators such that
By the ‘if’ part of Noether's Second Theorem, there exist variational symmetries of equation (3.7) whose generator is of the form
where is an arbitrary function. In other words, there exist functions such that
Consequently, for arbitrary

`and , is a characteristic of variational symmetries for the original variational problem (2.1). This implies that the set of variational symmetries for equation (2.1) depends on more than`

**g***R*independent arbitrary functions, contradicting our original assumption. Hence, the relations (3.5) cannot be dependent.

Conversely, given *R* independent relations between the Euler–Lagrange equations, Olver's ‘if’ proof applied to each one shows that there are characteristics of variational symmetries that depend on *R* independent arbitrary functions, namely
3.9
Thus, we arrive at the general form of Noether's Second Theorem.

### Theorem 3.2

*The variational problem (2.1) admits an infinite-dimensional Lie algebra of variational symmetry generators whose characteristics depend on R independent arbitrary functions and their derivatives if and only if there exist differential operators* *that yield R independent differential relations,
*
3.10
*between the Euler–Lagrange equations. Given the relations (3.10), the corresponding characteristics are (3.9). Conversely, given the characteristics, the corresponding differential relations are (3.5).*

## 4. Constrained variational symmetries

Constraints on arbitrary functions in **Q** arise from the linearized symmetry condition for the Euler–Lagrange equation, coupled with the (linear) requirement that the symmetries are variational. Therefore, we now suppose that the characteristics of variational symmetries of equation (2.1) depend on functions that are subject to *S* linear differential constraints,
4.1
where each is a differential operator. We assume that this set of constraints is complete, in the sense that it yields no additional integrability conditions. The constraints can be incorporated into the Lagrangian (3.8), yielding
4.2
where *ν*^{1},…,*ν*^{s} are Lagrange multipliers. Taking variations of (3.7) with respect to ` g`, we obtain
4.3

If *S*<*R*, one may be able to eliminate the undetermined functions *ν*^{s} from equation (4.3), as will be illustrated by the next example. The elimination of a particular set of dependent variables from a differential system may be accomplished using algorithms in differential algebra. Hubert (2000, 2003) provides a careful and extensive summary of the state of the art to date. Differential elimination algorithms have been implemented in the Maple library packages `diffalg` and `rifsimp`. These algorithms come with a ‘certificate’; provided that the correct elimination term ordering is used, the elimination ideal is generated by those equations in the output that are independent of the variables in . This means that any equation that is algebraically or differentially derived from the input set, and is free of the elements of , can be derived from . If is empty, then the elimination ideal itself is empty; in this case, none of the equations that can be derived from the input set is independent of all variables in .

Incidentally, the elimination algorithm can be used to test directly whether or not an Euler–Lagrange system has a differential relation such as equation (3.10): simply replace {*E*^{α}(*L*)=0} with {*E*^{α}(*L*)−*f*^{α}=0} and eliminate . The resulting equations for {*f*^{α}} codify the ideal of differential relations on the expressions {*E*^{α}(*L*)}.

There are subtleties for nonlinear systems; indeed, the proof that the output of the algorithms has the stated properties is one of the most subtle and complex problems of differential algebra.

### Example 4.1

Suppose that **Q** depends on two functions `g`^{1}(*x*^{1},*x*^{2}) and `g`^{2}(*x*^{1},*x*^{2}) that are subject to the single constraint
4.4
(This type of constraint occurs when the variational symmetries include all area-preserving diffeomorphisms of the plane.) Then, equation (4.3) amounts to
and
By eliminating the Lagrange multiplier *ν*, we obtain a single differential relation between the Euler–Lagrange equations,
4.5
This is precisely the same constraint as would be obtained by using the local solution of equation (4.4),
(where `g` is entirely arbitrary) in Noether's Second Theorem. However, the Lagrange multiplier method has the advantage of working even when equation (4.1) cannot be solved explicitly.

When the system of constraints (4.1) does not allow the multipliers *ν*^{s} to be eliminated, the most that one can do is to construct conservation laws of the Euler–Lagrange equations, as follows. First determine a particular solution of equation (4.3) for *ν*^{s}; this can be done by inspection (which is fast), or by the homotopy method (which is systematic). The resulting solution is then substituted into
4.6
yielding a set of conservation laws that depend on ` g`. This set is independent of which particular solution is used. It can be shown that if

**Q**is homogeneous with respect to

`, the conservation law (4.6) is a multiple of the one that is obtained from Noether's (first) Theorem.`

**g**

### Example 4.2

As we discussed in §1, the Lagrangian
for the one-dimensional scalar wave equation,
4.7
admits variational symmetries with partly constrained characteristics. Indeed, the most general variational symmetry characteristic is *Q*=`g`^{1}(*x*,*t*)+`g`^{2}(*x*,*t*), where
So the modified Lagrangian (4.2) is

Taking variations with respect to ` g`=(

`g`

^{1},

`g`

^{2}) gives the identities which are satisfied by Then, the conservation laws (4.6) amount to when equation (4.7) holds.

There are no trivial conservation laws with *Q* non-zero.

### Example 4.3

For a more substantial example that produces interesting conservation laws, consider the two-dimensional shallow water equations from Lagrangian fluid mechanics. Each fluid particle is labelled by its position (*a*^{1},*a*^{2}) at some reference time, *t*=0, and (*x*,*y*)=(*x*(*a*^{1},*a*^{2},*t*),*y*(*a*^{1},*a*^{2},*t*)) is the position of the fluid particle at time *t*. We set and ; from here on, only the derivatives with respect to the label variables *a*^{i} are denoted by subscripts. Salmon (1983) introduced a Lagrangian for the shallow water equations; with constant Coriolis parameter *f*, it amounts to
where
is the fluid depth and *g* is the constant of gravity. To translate between the Eulerian and Lagrangian viewpoints, we need the identities
Calculating the Euler–Lagrange system yields the shallow water equations
4.8
These are supplemented by the continuity equation,
which is *not* an Euler–Lagrange equation in Salmon's formulation. The variational symmetries include the well-known particle relabelling symmetries; these are arbitrary area-preserving diffeomorphisms of label space, whose characteristics are (Bîlǎ *et al.* 2006)
Taking the three constraints on the functions ` g`=(

`g`

^{1},

`g`

^{2}) into account, the modified Lagrangian is Taking variations with respect to

`, we obtain which is satisfied by With these solutions`

**g***ν*

^{i}, the resulting conservation laws (4.6) are In particular, taking (

`g`

^{1},

`g`

^{2}) to be (1,0) and (0,1) in turn yields which were discovered in a (somewhat complicated) multisymplectic setting by Hydon (2005). Differentiating the first of these with respect to

*a*

^{2}, the second with respect to

*a*

^{1}and eliminating , we obtain the well-known conservation law for potential vorticity, So in this example, our extension of Noether's Second Theorem has led quickly and easily to some fundamental conservation laws. Conservation of potential vorticity also arises directly from Noether's Theorem, but considerable effort is needed to obtain it (see Bîlǎ

*et al.*2006).

## 5. From continuous to discrete: Noether's Second Theorem

For difference equations, the dependent variables are again **u**=(*u*^{1},…,*u*^{q}), but now the independent variables are **n**=(*n*^{1},…,*n*^{p}), where each *n*^{i} is an integer. The forward shift operators, *S*_{i}, are defined by
for all functions *f*; here is the Kronecker delta. The formal adjoint of *S*_{i} (with respect to the ℓ_{2} inner product) is the backward shift . We also use the multiple shifts, , and the forward difference operators,
where id denotes the identity map. (Here and in what follows, we use notation that is similar to the continuous case in order to highlight the similarities. To avoid confusion, we use a tilde to distinguish an operator from its continuous counterpart.)

For difference variational problems, the action is of the form
where now [**u**] denotes **u**(**n**) and finitely many of its shifts. Just as in the continuous case, we work formally, avoiding matters such as convergence. The Euler–Lagrange equations are
5.1
Generalized symmetries of the Euler–Lagrange equations have generators of the form
that satisfy the linearized symmetry condition,
Here, *Q*^{α}(**n**,[**u**]),*α*=1,…,*q*, are the components of the characteristic, **Q**(**n**,[**u**]). The symmetries are *variational* if they do not change the action, that is, if there exist functions such that
5.2
Summing equation (5.2) by parts yields the following condition, which is analogous to equation (2.5):
5.3
for some functions *P*^{i}. So, Noether's Theorem applies just as in the continuous case: every variational symmetry characteristic yields a conservation law of the Euler–Lagrange equations, namely

With the above notation, the analogue of Noether's Second Theorem for the difference calculus of variations is as follows.

### Theorem 5.1

*The difference variational problem* *admits an infinite-dimensional Lie algebra of variational symmetry generators whose characteristics depend on R independent arbitrary functions and their derivatives if and only if there exist difference operators* *that yield R independent difference relations,
*
5.4
*between the Euler–Lagrange equations. Given the relations (5.4), the corresponding characteristics are
*
5.5
*Conversely, given the characteristics, the corresponding difference relations are
*
5.6
*and consequently
*

The proof completely replicates our proof of the continuous version, except that the following substitutions are made: With these substitutions, the identity (3.6) holds for difference equations, so the set of relations is invariant under locally invertible changes of the arbitrary functions.

### Example 5.1

For the interaction of a scalar particle with an electromagnetic field (see example 3.1), Christiansen & Halvorsen (2011) discovered a finite-difference approximation that preserves the gauge symmetries as variational symmetries. The mesh **x**(**n**) is uniformly spaced in each direction, with step lengths
It is useful to introduce the scaled forward difference operators
so that tends to *D*_{μ} in the limit as *h*^{μ} tends to zero. Note that
the adjoint of the (scaled) forward difference operator is the negative of the (scaled) backward difference operator. Let denote the approximation to the wave function *ψ* at **x**(**n**). Christiansen & Halvorsen (2011) used a Yee discretization (see their paper for details) to approximate *A*_{μ} on the edge that connects the points **x**(**n**) and *S*_{μ}**x**(**n**); we denote this approximation by . As before, indices are raised and lowered using the metric *η*=diag{−1,1,1,1}. Up to a sign, the Lagrangian for the scheme is
5.7
where, for each *μ*,*ν*=0,…,3,
and
Therefore, the Euler–Lagrange equations that are obtained by varying , and are
Note that
tends to as *h*^{μ} approaches zero, so the scheme has the correct limiting behaviour.

The above discretization preserves the gauge symmetries as variational symmetries. Explicitly, these are
where now *λ* is an arbitrary real-valued function of **n**. As in the continuous case, the Lagrangian is invariant, so . The characteristics of the gauge symmetries have components
where `g` is an arbitrary real-valued function of **n**. Consequently, the discrete version of Noether's Second Theorem immediately yields the difference relation
which Christiansen & Halvorsen obtained with the aid of Noether's First Theorem.

## 6. Variational symmetries with difference constraints

If the functions ` g` are subject to a (complete) set of

*S*linear difference constraints, 6.1 we incorporate these using the same approach as for differential equations. First, form the new Lagrangian, 6.2 where

*ν*

^{1},…,

*ν*

^{s}are Lagrange multipliers. Then, take variations with respect to

`to obtain 6.3 Just as in the continuous case, these relations yield conservation laws of the Euler–Lagrange equations (5.1), namely 6.4 It may also be possible to eliminate the Lagrange multipliers from equation (6.3) to obtain difference relations between the Euler–Lagrange equations.`

**g**

### Example 6.1

The lattice Korteweg–de Vries (KdV) equation is
6.5
where *U*_{i,j} denotes the value of the dependent variable *U* at the point (*n*^{1}+*i*,*n*^{2}+*j*) (see Grammaticos *et al.* 1991 for details). This is not an Euler–Lagrange equation as it stands, but it can be turned into one by introducing a potential, *u*, such that
Then, equation (6.5) amounts to
where
Clearly, the variable *U* is unaffected by gauge transformations
so these are symmetries of the Euler–Lagrange equation. Their characteristic is *Q*=`g`_{0,0}, where `g`_{1,0}−`g`_{0,1}=0; therefore,
and so the gauge symmetries are variational. Now, vary `g` for the new Lagrangian
to obtain the relation
One obvious solution is
6.6
the corresponding conservation laws (6.4) are
Note that by setting *ν*_{0,0}=0 in equation (6.6), we obtain the well-known discrete potential KdV equation,
6.7
So the constraint on the gauge symmetry provides a link between the lattice KdV equation and its related potential form. This observation applies similarly to many integrable difference equations.

## 7. Conclusion

We have shown that there is a complete correspondence between Noether's Second Theorem for differential and difference equations, and that the same is true where characteristics of variational symmetries depend on partly constrained functions. Our approach yields, *mutatis mutandis*, the corresponding results for differential–difference equations.

- Received March 9, 2011.
- Accepted May 26, 2011.

- This journal is © 2011 The Royal Society