Jump to content

Differentiation in Fréchet spaces: Difference between revisions

From Wikipedia, the free encyclopedia
Content deleted Content added
m Reverting possible vandalism by Dubey pravin to version by 66.25.206.181. False positive? Report it. Thanks, ClueBot NG. (1803000) (Bot)
No edit summary
Line 1: Line 1:
{{Merge to |Gâteaux_derivative|date=August 2014}}

In [[mathematics]], in particular in [[functional analysis]] and [[nonlinear analysis]], it is possible to define the [[derivative (generalizations)|derivative]] of a function between two [[Fréchet space]]s. This notion of differentiation is significantly weaker than the [[Fréchet derivative|derivative in a Banach space]]. 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]].
In [[mathematics]], in particular in [[functional analysis]] and [[nonlinear analysis]], it is possible to define the [[derivative (generalizations)|derivative]] of a function between two [[Fréchet space]]s. This notion of differentiation is significantly weaker than the [[Fréchet derivative|derivative in a Banach space]]. 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]].



Revision as of 20:04, 29 August 2014

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 is significantly weaker than the derivative in a Banach space. 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 Gâteaux derivative. Specifically, let X and Y be Fréchet spaces, UX be an open set, and F : UY be a function. The directional derivative of F in the direction vX is defined by

if the limit exists. One says that F is continuously differentiable, or C1 if the limit exists for all v ∈ X and the mapping

DF:U x XY

is a continuous map.

Higher order derivatives are defined inductively via

A function is said to be Ck if DkF : U x X x Xx ... x XY is continuous. It is C, or smooth if it is Ck for every k.

Properties

Let X, Y, and Z be Fréchet spaces. Suppose that U is an open subset of X, V is an open subset of Y, and F : UV, G : VZ are a pair of C1 functions. Then the following properties hold:

  • (Fundamental theorem of calculus.)
If the line segment from a to b lies entirely within U, then
.
  • (The chain rule.)
D(G o F)(u)x = DG(F(u))DF(u)x for all u ε U and x ε X.
  • (Linearity.)
DF(u)x is linear in x.[citation needed] More generally, if F is Ck, then DF(u){x1,...,xk} is multilinear in the x's.
  • (Taylor's theorem with remainder.)
Suppose that the line segment between u ε U and u+h lies entirely within u. If F is Ck then
where the remainder term is given by
  • (Commutativity of directional derivatives.) If F is Ck, then
for every permutation σ of {1,2,...,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.

Consequences in differential geometry

The existence of a chain rule allows for the definition of a manifold modeled on a Frèchet 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

  1. Hamilton, R. S. (1982). "The inverse function theorem of Nash and Moser". Bull. AMS. 7 (7): 65–222. doi:10.1090/S0273-0979-1982-15004-2. MR 0656198.
pFad - Phonifier reborn

Pfad - The Proxy pFad of © 2024 Garber Painting. All rights reserved.

Note: This service is not intended for secure transactions such as banking, social media, email, or purchasing. Use at your own risk. We assume no liability whatsoever for broken pages.


Alternative Proxies:

Alternative Proxy

pFad Proxy

pFad v3 Proxy

pFad v4 Proxy