Unfolding (functions) explained

In mathematics, an unfolding of a smooth real-valued function ƒ on a smooth manifold, is a certain family of functions that includes ƒ.

Definition

Let

be a smooth manifold and consider a smooth mapping

f:M\toR.

Let us assume that for given

x₀\inM

and

y₀\inR

we have

f(x₀₎=y₀

. Let

be a smooth

-dimensional manifold, and consider the family of mappings (parameterised by

) given by

F:M x N\toR.

We say that

is a

-parameter unfolding of

F(x,0)=f(x)

for all

In other words the functions

f:M\toR

and

F:M x \{0\}\toR

are the same: the function

is contained in, or is unfolded by, the family

Example

Let

f:R²\toR

be given by

f(x,y)=x²+y^5.

An example of an unfolding of

would be

F:R² x R³\toR

given by

F((x,y),(a,b,c))=x²+y⁵+ay+by²+cy^3.

As is the case with unfoldings,

and

are called variables, and

and

are called parameters, since they parameterise the unfolding.

Well-behaved unfoldings

In practice we require that the unfoldings have certain properties. In

is a smooth mapping from

and so belongs to the function space

C^infty(M,R).

As we vary the parameters of the unfolding, we get different elements of the function space. Thus, the unfolding induces a function

\Phi:N\toC^infty(M,R).

The space

\operatorname{diff}(M) x \operatorname{diff}(R)

, where

\operatorname{diff}(M)

denotes the group of diffeomorphisms of

etc., acts on

C^infty(M,R).

The action is given by

(\phi,\psi) ⋅ f=\psi\circf\circ\phi^-1.

lies in the orbit of

under this action then there is a diffeomorphic change of coordinates in

and

, which takes

(and vice versa). One property that we can impose is that

\operatorname{Im}(\Phi)\pitchfork\operatorname{orb}(f)

where "

\pitchfork

" denotes "transverse to". This property ensures that as we vary the unfolding parameters we can predict – by knowing how the orbit foliates

C^infty(M,R)

– how the resulting functions will vary.

Versal unfoldings

There is an idea of a versal unfolding. Every versal unfolding has the property that

\operatorname{Im}(\Phi)\pitchfork\operatorname{orb}(f)

, but the converse is false. Let

x_1,\ldots,x_n

be local coordinates on

, and let

l{O}(x_1,\ldots,x_n)

denote the ring of smooth functions. We define the Jacobian ideal of

, denoted by

J_f

, as follows:

J_f:=\left\langle

	\partialf
	\partialx₁

,\ldots,

	\partialf
	\partialx_n

\right\rangle.

Then a basis for a versal unfolding of

is given by the quotient

	l{O
	(x

_1,\ldots,x_n)}{J_f}

This quotient is known as the local algebra of

. The dimension of the local algebra is called the Milnor number of

. The minimum number of unfolding parameters for a versal unfolding is equal to the Milnor number; that is not to say that every unfolding with that many parameters will be versal. Consider the function

f(x,y)=x²+y⁵

. A calculation shows that

	l{O
	(x,y)}{\langle

2x,5y⁴\rangle}=\{y,y^2,y^3\} .

This means that

\{y,y^2,y^3\}

give a basis for a versal unfolding, and that

F((x,y),(a,b,c))=x²+y⁵+ay+by²+cy³

is a versal unfolding. A versal unfolding with the minimum possible number of unfolding parameters is called a miniversal unfolding.

Bifurcations sets of unfoldings

An important object associated to an unfolding is its bifurcation set. This set lives in the parameter space of the unfolding, and gives all parameter values for which the resulting function has degenerate singularities.

Other terminology

Sometimes unfoldings are called deformations, versal unfoldings are called versal deformations, etc.

References

V. I. Arnold, S. M. Gussein-Zade & A. N. Varchenko, Singularities of differentiable maps, Volume 1, Birkhäuser, (1985).
J. W. Bruce & P. J. Giblin, Curves & singularities, second edition, Cambridge University press, (1992).