Differentiable vector–valued functions from Euclidean space explained

In the mathematical discipline of functional analysis, a differentiable vector-valued function from Euclidean space is a differentiable function valued in a topological vector space (TVS) whose domains is a subset of some finite-dimensional Euclidean space. It is possible to generalize the notion of derivative to functions whose domain and codomain are subsets of arbitrary topological vector spaces (TVSs) in multiple ways. But when the domain of a TVS-valued function is a subset of a finite-dimensional Euclidean space then many of these notions become logically equivalent resulting in a much more limited number of generalizations of the derivative and additionally, differentiability is also more well-behaved compared to the general case. This article presents the theory of

-times continuously differentiable functions on an open subset

\Omega

of Euclidean space

\Rⁿ

(

1\leqn<infty

), which is an important special case of differentiation between arbitrary TVSs. This importance stems partially from the fact that every finite-dimensional vector subspace of a Hausdorff topological vector space is TVS isomorphic to Euclidean space

\Rⁿ

so that, for example, this special case can be applied to any function whose domain is an arbitrary Hausdorff TVS by restricting it to finite-dimensional vector subspaces.

All vector spaces will be assumed to be over the field

where

is either the real numbers

or the complex numbers

\Complex.

Continuously differentiable vector-valued functions

A map

which may also be denoted by

f⁽⁰⁾,

between two topological spaces is said to be or if it is continuous. A topological embedding may also be called a .

Curves

Differentiable curves are an important special case of differentiable vector-valued (i.e. TVS-valued) functions which, in particular, are used in the definition of the Gateaux derivative. They are fundamental to the analysis of maps between two arbitrary topological vector spaces

X\toY

and so also to the analysis of TVS-valued maps from Euclidean spaces, which is the focus of this article.

A continuous map

f:I\toX

from a subset

I\subseteqR

that is valued in a topological vector space

is said to be ( or ) if for all

t\inI,

it is which by definition means the following limit in

exists:

f^(t) := f^(t) = \lim_ \frac = \lim_ \frac

where in order for this limit to even be well-defined,

must be an accumulation point of

f:I\toX

is differentiable then it is said to be or if its , which is the induced map

f^\prime=f⁽¹⁾:I\toX,

is continuous. Using induction on

1<k\in\N,

the map

f:I\toX

is or if its

k-1^th

derivative

f^(k-1):I\toX

is continuously differentiable, in which case the is the map

f^(k):=\left(f^(k-1)\right)^\prime:I\toX.

It is called ,

C^infty,

or if it is

-times continuously differentiable for every integer

k\in\N.

For

k\in\N,

it is called if it is

k-1

-times continuous differentiable and

f^(k-1):I\toX

is differentiable.

A continuous function

f:I\toX

from a non-empty and non-degenerate interval

I\subseteq\R

into a topological space

is called a or a in

A in

is a curve in

whose domain is compact while an or in

is a path in

that is also a topological embedding. For any

k\in\{1,2,\ldots,infty\},

a curve

f:I\toX

valued in a topological vector space

is called a if it is a topological embedding and a

C^k

curve such that

f^\prime(t) ≠ 0

for every

t\inI,

where it is called a if it is also a path (or equivalently, also a

C⁰

-arc) in addition to being a

C^k

-embedding.

Differentiability on Euclidean space

The definition given above for curves are now extended from functions valued defined on subsets of

to functions defined on open subsets of finite-dimensional Euclidean spaces.

Throughout, let

\Omega

be an open subset of

\R^n,

where

n\geq1

is an integer. Suppose

t=\left(t_1,\ldots,t_n\right)\in\Omega

and

f:\operatorname{domain}f\toY

is a function such that

t\in\operatorname{domain}f

with

an accumulation point of

\operatorname{domain}f.

Then

is if there exist

vectors

e_1,\ldots,e_n

called the , such that

\lim_ \frac = 0 \text Y

where

p=\left(p_1,\ldots,p_n\right).

is differentiable at a point then it is continuous at that point. If

is differentiable at every point in some subset

of its domain then

is said to be ( or ) , where if the subset

is not mentioned then this means that it is differentiable at every point in its domain. If

is differentiable and if each of its partial derivatives is a continuous function then

is said to be ( or ) or For

k\in\N,

having defined what it means for a function

to be

C^k

(or

times continuously differentiable), say that

is or that if

is continuously differentiable and each of its partial derivatives is

C^k.

Say that

C^infty,

or if

C^k

for all

k=0,1,\ldots.

The of a function

is the closure (taken in its domain

\operatorname{domain}f

) of the set

\{x\in\operatorname{domain}f:f(x) ≠ 0\}.

Spaces of C^k vector-valued functions

Space of C^k functions

For any

k=0,1,\ldots,infty,

let

C^k(\Omega;Y)

denote the vector space of all

C^k

-valued maps defined on

\Omega

and let

	k(\Omega;Y)
C
	c

denote the vector subspace of

C^k(\Omega;Y)

consisting of all maps in

C^k(\Omega;Y)

that have compact support. Let

C^k(\Omega)

denote

C^k(\Omega;F)

and

	k(\Omega)
C
	c

denote

	k(\Omega;
C
	c

F).

Give

	k(\Omega;Y)
C
	c

the topology of uniform convergence of the functions together with their derivatives of order

<k+1

on the compact subsets of

\Omega.

Suppose

\Omega₁\subseteq\Omega₂\subseteq …

is a sequence of relatively compact open subsets of

\Omega

whose union is

\Omega

and that satisfy

\overline{\Omega_i}\subseteq\Omega_i+1

for all

Suppose that

\left(V_{\alpha\right)}_\alpha

is a basis of neighborhoods of the origin in

Then for any integer

\ell<k+1,

the sets:

\mathcal_ := \left\

form a basis of neighborhoods of the origin for

C^k(\Omega;Y)

\ell,

and

\alpha\inA

vary in all possible ways. If

\Omega

is a countable union of compact subsets and

is a Fréchet space, then so is

C^(\Omega;Y).

Note that

l{U}_i,

is convex whenever

U_\alpha

is convex. If

is metrizable (resp. complete, locally convex, Hausdorff) then so is

C^k(\Omega;Y).

(p_\alpha)_\alpha

is a basis of continuous seminorms for

then a basis of continuous seminorms on

C^k(\Omega;Y)

is:

\mu_(f) := \sup_ \left(\sum_

\leq l

p_\alpha\left(\left(\partial / \partial p\right)^q f (p)\right)\right)as

\ell,

and

\alpha\inA

vary in all possible ways.

Space of C^k functions with support in a compact subset

The definition of the topology of the space of test functions is now duplicated and generalized. For any compact subset

K\subseteq\Omega,

denote the set of all

C^k(\Omega;Y)

whose support lies in

(in particular, if

f\inC^k(K;Y)

then the domain of

\Omega

rather than

) and give it the subspace topology induced by

C^k(\Omega;Y).

is a compact space and

is a Banach space, then

C^0(K;Y)

becomes a Banach space normed by

\|f\|:=\sup_\omega\|f(\omega)\|.

Let

C^k(K)

denote

C^k(K;F).

For any two compact subsets

K\subseteqL\subseteq\Omega,

the inclusion

\operatorname_^ : C^k(K;Y) \to C^k(L;Y)

is an embedding of TVSs and that the union of all

C^k(K;Y),

varies over the compact subsets of

\Omega,

	k(\Omega;Y).
C
	c

Space of compactly support C^k functions

For any compact subset

K\subseteq\Omega,

let

\operatorname_K : C^k(K;Y) \to C_c^k(\Omega;Y)

denote the inclusion map and endow

	k(\Omega;Y)
C
	c

with the strongest topology making all

\operatorname{In}_K

continuous, which is known as the final topology induced by these map. The spaces

C^k(K;Y)

and maps

	K₂
\operatorname{In}
	K₁

form a direct system (directed by the compact subsets of

\Omega

) whose limit in the category of TVSs is

	k(\Omega;Y)
C
	c

together with the injections

\operatorname{In}_K.

The spaces

	k\left(\overline{\Omega
C
	i};

Y\right)

and maps

\operatorname{In}
	\overline{\Omega_i

}^ also form a direct system (directed by the total order

) whose limit in the category of TVSs is

	k(\Omega;Y)
C
	c

together with the injections

\operatorname{In}
	\overline{\Omega_i

}. Each embedding

\operatorname{In}_K

is an embedding of TVSs. A subset

	k(\Omega;Y)
C
	c

is a neighborhood of the origin in

	k(\Omega;Y)
C
	c

if and only if

S\capC^k(K;Y)

is a neighborhood of the origin in

C^k(K;Y)

for every compact

K\subseteq\Omega.

This direct limit topology (i.e. the final topology) on

	infty(\Omega)
C
	c

is known as the .

is a Hausdorff locally convex space,

is a TVS, and

	k(\Omega;Y)
C
	c

\toT

is a linear map, then

is continuous if and only if for all compact

K\subseteq\Omega,

the restriction of

C^k(K;Y)

is continuous. The statement remains true if "all compact

K\subseteq\Omega

" is replaced with "all

K:=\overline{\Omega}_i

Identification as a tensor product

Suppose henceforth that

is Hausdorff. Given a function

f\inC^k(\Omega)

and a vector

y\inY,

let

f ⊗ y

denote the map

f ⊗ y:\Omega\toY

defined by

(f ⊗ y)(p)=f(p)y.

This defines a bilinear map

⊗ :C^k(\Omega) x Y\toC^k(\Omega;Y)

into the space of functions whose image is contained in a finite-dimensional vector subspace of

this bilinear map turns this subspace into a tensor product of

C^k(\Omega)

and

which we will denote by

C^k(\Omega) ⊗ Y.

Furthermore, if

	k(\Omega)
C
	c

⊗ Y

denotes the vector subspace of

C^k(\Omega) ⊗ Y

consisting of all functions with compact support, then

	k(\Omega)
C
	c

⊗ Y

is a tensor product of

	k(\Omega)
C
	c

and

is locally compact then

	0
C
	c

(\Omega) ⊗ Y

is dense in

C^0(\Omega;X)

while if

is an open subset of

\Rⁿ

then

	infty
C
	c

(\Omega) ⊗ Y

is dense in

C^k(\Omega;X).

Differentiable vector–valued functions from Euclidean space explained

Continuously differentiable vector-valued functions

Curves

Differentiability on Euclidean space

Spaces of Ck vector-valued functions

Space of Ck functions

Space of Ck functions with support in a compact subset

Space of compactly support Ck functions

Identification as a tensor product

Spaces of C^k vector-valued functions

Space of C^k functions

Space of C^k functions with support in a compact subset

Space of compactly support C^k functions