Differentiation in Fréchet spaces explained

In mathematics, in particular in functional analysis and nonlinear analysis, it is possible to define the derivative of a function between two Fréchet spaces. This notion of differentiation, as it is Gateaux derivative between Fréchet spaces, is significantly weaker than the derivative in a Banach space, even between general topological vector spaces. Nevertheless, it is the weakest notion of differentiation for which many of the familiar theorems from calculus hold. In particular, the chain rule is true. With some additional constraints on the Fréchet spaces and functions involved, there is an analog of the inverse function theorem called the Nash–Moser inverse function theorem, having wide applications in nonlinear analysis and differential geometry.

Mathematical details

Formally, the definition of differentiation is identical to the Gateaux derivative. Specifically, let

and

be Fréchet spaces,

U\subseteqX

be an open set, and

F:U\toY

be a function. The directional derivative of

in the direction

v\inX

is defined by

DF(u)v = \lim_ \frac

if the limit exists. One says that

is continuously differentiable, or

C¹

if the limit exists for all

v\inX

and the mapping

DF : U \times X \to Y

is a continuous map.

Higher order derivatives are defined inductively via $D^F(u) \left\ = \lim_ \frac.$ A function is said to be

C^k

D^kF:U x X x X x … x X\toY

is continuous. It is

C^infty,

or smooth if it is

C^k

for every

Properties

Let

X,Y,

and

be Fréchet spaces. Suppose that

is an open subset of

and

F:U\toV,

G:V\toZ

are a pair of

C¹

functions. Then the following properties hold:

Fundamental theorem of calculus. If the line segment from

lies entirely within

then

F(b) - F(a) = \int_0^1 DF(a + (b - a) t) \cdot (b - a) dt.

The chain rule. For all

u\inU

and

x\inX,

D(G \circ F)(u) x = DG(F(u)) DF(u) x

Linearity.

DF(u)x

is linear in

More generally, if

C^k,

then

DF(u)\left\{x_1,\ldots,x_k\right\}

is multilinear in the

's.

Taylor's theorem with remainder. Suppose that the line segment between

u\inU

and

u+h

lies entirely within

C^k

then

F(u+h) = F(u) + DF(u)h + \frac D^2F(u) \ + \cdots + \frac D^F(u) \ + R_k

where the remainder term is given by

R_k(u,h) = \frac \int_0^1(1-t)^ D^kF(u+th) \dt

Commutativity of directional derivatives. If

C^k,

then

D^kF(u) \left\ = D^kF(u) \left\

for every permutation σ of

\{1,2,\ldots,k\}.

The proofs of many of these properties rely fundamentally on the fact that it is possible to define the Riemann integral of continuous curves in a Fréchet space.

Smooth mappings

Surprisingly, a mapping between open subset of Fréchet spaces is smooth (infinitely often differentiable) if it maps smooth curves to smooth curves; see Convenient analysis.Moreover, smooth curves in spaces of smooth functions are just smooth functions of one variable more.

Consequences in differential geometry

The existence of a chain rule allows for the definition of a manifold modeled on a Fréchet space: a Fréchet manifold. Furthermore, the linearity of the derivative implies that there is an analog of the tangent bundle for Fréchet manifolds.

Tame Fréchet spaces

Frequently the Fréchet spaces that arise in practical applications of the derivative enjoy an additional property: they are tame. Roughly speaking, a tame Fréchet space is one which is almost a Banach space. On tame spaces, it is possible to define a preferred class of mappings, known as tame maps. On the category of tame spaces under tame maps, the underlying topology is strong enough to support a fully fledged theory of differential topology. Within this context, many more techniques from calculus hold. In particular, there are versions of the inverse and implicit function theorems.

References

Hamilton, R. S.. Richard S. Hamilton. The inverse function theorem of Nash and Moser. Bull. Amer. Math. Soc.. 1. 1982. 65–222. 10.1090/S0273-0979-1982-15004-2. 7. 656198. free.