Differentiable vector-valued functions from Euclidean space

Throughout, let ${\displaystyle k\in \{0,1,\ldots ,\infty \}}$  and let ${\displaystyle \Omega }$  be either:

1. an open subset of ${\displaystyle \mathbb {R} ^{n}}$ , where ${\displaystyle n\geq 1}$  is an integer, or else
2. a locally compact topological space, in which k can only be 0,

and let ${\displaystyle Y}$  be a topological vector space (TVS).

Definition^[1] Suppose ${\displaystyle p^{0}=\left(p_{1}^{0},\ldots ,p_{n}^{0}\right)\in \Omega }$  and ${\displaystyle f:\operatorname {Dom} f\to Y}$  is a function such that ${\displaystyle p^{0}\in \operatorname {Dom} f}$  with ${\displaystyle p^{0}}$  a limit point of ${\displaystyle \operatorname {Dom} f}$ . Then we say that f is differentiable at ${\displaystyle p^{0}}$  if there exist n vectors ${\displaystyle e_{1},\ldots ,e_{n}}$  in Y, called the partial derivatives of f, such that

${\displaystyle \lim _{p\to p^{0},p\in \operatorname {Dom} f}{\frac {f(p)-f\left(p^{0}\right)-\sum _{i=1}^{n}\left(p_{i}-p_{i}^{0}\right)e_{i}}{\left\|p-p^{0}\right\|_{2}}}=0}$  in Y

where ${\displaystyle p=\left(p_{1},\ldots ,p_{n}\right)}$ .

Note that if f is differentiable at a point then it is continuous at that point.^[1] Say that f is ${\displaystyle C^{0}}$  if it is continuous. If f is differentiable at every point in some set ${\displaystyle S\subseteq \Omega }$  then we say that f is differentiable in S. If f is differentiable at every point of its ___domain and if each of its partial derivatives is a continuous function then we say that f is continuously differentiable or ${\displaystyle C^{1}}$ .^[1] Having defined what it means for a function f to be ${\displaystyle C^{k}}$  (or k times continuously differentiable), say that f is k + 1 times continuously differentiable or that f is ${\displaystyle C^{k+1}}$  if f is continuously differentiable and each of its partial derivatives is ${\displaystyle C^{k}}$ . Say that f is ${\displaystyle C^{\infty }}$ , smooth, or infinitely differentiable if f is ${\displaystyle C^{k}}$  for all ${\displaystyle k=0,1,\ldots }$ . If ${\displaystyle f:\Omega \to Y}$  is any function then its support is the closure (in ${\displaystyle \Omega }$ ) of the set ${\displaystyle \{x\in \operatorname {Dom} f:f(x)\neq 0\}}$ .

For any ${\displaystyle k=0,1,\ldots ,\infty }$ , let ${\displaystyle C^{k}\left(\Omega ;Y\right)}$  denote the vector space of all ${\displaystyle C^{k}}$  Y-valued maps defined on ${\displaystyle \Omega }$  and let ${\displaystyle C_{c}^{k}\left(\Omega ;Y\right)}$  denote the vector subspace of ${\displaystyle C^{k}\left(\Omega ;Y\right)}$  consisting of all maps in ${\displaystyle C^{k}\left(\Omega ;Y\right)}$  that have compact support. Let ${\displaystyle C^{k}\left(\Omega \right)}$  denote ${\displaystyle C^{k}\left(\Omega ;\mathbb {F} \right)}$  and ${\displaystyle C_{c}^{k}\left(\Omega \right)}$  denote ${\displaystyle C_{c}^{k}\left(\Omega ;\mathbb {F} \right)}$ . We give ${\displaystyle C_{c}^{k}\left(\Omega ;Y\right)}$  the topology of uniform convergence of the functions together with their derivatives of order < k + 1 on the compact subsets of ${\displaystyle \Omega }$ .^[1] Suppose ${\displaystyle \Omega _{1}\subseteq \Omega _{2}\subseteq \cdots }$  is a sequence of relatively compact open subsets of ${\displaystyle \Omega }$  whose union is ${\displaystyle \Omega }$  and that satisfy ${\displaystyle {\overline {\Omega _{i}}}\subseteq \Omega _{i+1}}$  for all i. Suppose that ${\displaystyle \left(V_{\alpha }\right)_{\alpha \in A}}$  is a basis of neighborhoods of the origin in Y. Then for any integer ${\displaystyle l<k+1}$ , the sets:

${\displaystyle {\mathcal {U}}_{i,l,\alpha }:=\left\{f\in C^{k}\left(\Omega ;Y\right):\left(\partial /\partial p\right)^{q}f(p)\in U_{\alpha }{\text{ for all }}p\in \Omega _{i}{\text{ and all }}q\in \mathbb {N} ^{n},|q|\leq l\right\}}$ 

form a basis of neighborhoods of the origin for ${\displaystyle C^{k}\left(\Omega ;Y\right)}$  as i, l, and ${\displaystyle \alpha \in A}$  vary in all possible ways. If ${\displaystyle \Omega }$  is a countable union of compact subsets and Y is a Fréchet space, then so is ${\displaystyle C^{k}\left(\Omega ;Y\right)}$ . Note that ${\displaystyle {\mathcal {U}}_{i,l,\alpha }}$  is convex whenever ${\displaystyle U_{\alpha }}$  is convex. If Y is metrizable (resp. complete, locally convex, Hausdorff) then so is ${\displaystyle C^{k}\left(\Omega ;Y\right)}$ .^[1][2] If ${\displaystyle \left(p_{\alpha }\right)_{\alpha \in A}}$  is a basis of continuous seminorms for Y then a basis of continuous seminorms on ${\displaystyle C^{k}\left(\Omega ;Y\right)}$  is:

${\displaystyle \mu _{i,l,\alpha }\left(f\right):=\sup _{y\in \Omega _{i}}\left(\sum _{|q|\leq l}p_{\alpha }\left(\left(\partial /\partial p\right)^{q}f(p)\right)\right)}$ 

as i, l, and ${\displaystyle \alpha \in A}$  vary in all possible ways.^[1]

If ${\displaystyle \Omega }$  is a compact space and Y is a Banach space, then ${\displaystyle C^{0}\left(\Omega ;Y\right)}$  becomes a Banach space normed by ${\displaystyle \|f\|:=\sup _{\omega \in \Omega }\|f(\omega )\|}$ .^[2]

We now duplicate the definition of the topology of the space of test functions. For any compact subset ${\displaystyle K\subseteq \Omega }$ , let ${\displaystyle C^{k}\left(K;Y\right)}$  denote the set of all f in ${\displaystyle C^{k}\left(\Omega ;Y\right)}$  whose support lies in K (in particular, if ${\displaystyle f\in C^{k}\left(K;Y\right)}$  then the ___domain of f is ${\displaystyle \Omega }$  rather than K) and give ${\displaystyle C^{k}\left(K;Y\right)}$  the subspace topology induced by ${\displaystyle C^{k}\left(\Omega ;Y\right)}$ .^[1] Let ${\displaystyle C^{k}\left(K\right)}$  denote ${\displaystyle C^{k}\left(K;\mathbb {F} \right)}$ . Note that for any two compact subsets ${\displaystyle K_{1}\subseteq K_{2}\subseteq \Omega }$ , the natural inclusion ${\displaystyle \operatorname {In} _{K_{1}}^{K_{2}}:C^{k}\left(K_{1};Y\right)\to C^{k}\left(K_{2};Y\right)}$  is an embedding of TVSs and that the union of all ${\displaystyle C^{k}\left(K;Y\right)}$ , as K varies over the compact subsets of ${\displaystyle \Omega }$ , is ${\displaystyle C_{c}^{k}\left(\Omega ;Y\right)}$ .

For any compact subset ${\displaystyle K\subseteq \Omega }$ , let ${\displaystyle \operatorname {In} _{K}:C^{k}\left(K;Y\right)\to C_{c}^{k}\left(\Omega ;Y\right)}$  be the natural inclusion and give ${\displaystyle C_{c}^{k}\left(\Omega ;Y\right)}$  the strongest topology making all ${\displaystyle \operatorname {In} _{K}}$  continuous. The spaces ${\displaystyle C^{k}\left(K;Y\right)}$  and maps ${\displaystyle \operatorname {In} _{K_{1}}^{K_{2}}}$  form a direct system (directed by the compact subsets of ${\displaystyle \Omega }$ ) whose limit in the category of TVSs is ${\displaystyle C_{c}^{k}\left(\Omega ;Y\right)}$  together with the natural injections ${\displaystyle \operatorname {In} _{K}}$ .^[1] The spaces ${\displaystyle C^{k}\left({\overline {\Omega _{i}}};Y\right)}$  and maps ${\displaystyle \operatorname {In} _{\overline {\Omega _{i}}}^{\overline {\Omega _{j}}}}$  also form a direct system (directed by the total order ${\displaystyle \mathbb {N} }$ ) whose limit in the category of TVSs is ${\displaystyle C_{c}^{k}\left(\Omega ;Y\right)}$  together with the natural injections ${\displaystyle \operatorname {In} _{\overline {\Omega _{i}}}}$ .^[1] Each natural embedding ${\displaystyle \operatorname {In} _{K}}$  is an embedding of TVSs. A subset S of ${\displaystyle C_{c}^{k}\left(\Omega ;Y\right)}$  is a neighborhood of the origin in ${\displaystyle C_{c}^{k}\left(\Omega ;Y\right)}$  if and only if ${\displaystyle S\cap C^{k}\left(K;Y\right)}$  is a neighborhood of the origin in ${\displaystyle C^{k}\left(K;Y\right)}$  for every compact ${\displaystyle K\subseteq \Omega }$ . This direct limit topology on ${\displaystyle C_{c}^{\infty }\left(\Omega \right)}$  is known as the canonical LF topology.

If Y is a Hausdorff locally convex space, T is a TVS, and ${\displaystyle u:C_{c}^{k}\left(\Omega ;Y\right)\to T}$  is a linear map, then u is continuous if and only if for all compact ${\displaystyle K\subseteq \Omega }$ , the restriction of u to ${\displaystyle C^{k}\left(K;Y\right)}$  is continuous.^[1] One replace "all compact ${\displaystyle K\subseteq \Omega }$ " with "all ${\displaystyle K:={\overline {\Omega _{i}}}}$ ".

Theorem^[1] Let m be a positive integer and let ${\displaystyle \Delta }$  be an open subset of ${\displaystyle \mathbb {R} ^{m}}$ . Given ${\displaystyle \phi \in C^{k}\left(\Omega \times \Delta \right)}$ , for any ${\displaystyle y\in \Delta }$  let ${\displaystyle \phi _{y}:\Omega \to \mathbb {F} }$  be defined by ${\displaystyle \phi _{y}(x)=\phi (x,y)}$ ; and let ${\displaystyle I_{k}\left(\phi \right):\Delta \to C^{k}\left(\Omega \right)}$  be defined by ${\displaystyle I_{k}\left(\phi \right)(y):=\phi _{y}}$ . Then ${\displaystyle I_{\infty }:C^{\infty }\left(\Omega \times \Delta \right)\to C^{\infty }\left(\Delta ;C^{\infty }\left(\Omega \right)\right)}$  is a (surjective) isomorphism of TVSs. Furthermore, the restriction ${\displaystyle I_{\infty }{\big \vert }_{C_{c}^{\infty }\left(\Omega \times \Delta \right)}:C_{c}^{\infty }\left(\Omega \times \Delta \right)\to C_{c}^{\infty }\left(\Delta ;C_{c}^{\infty }\left(\Omega \right)\right)}$  is an isomorphism of TVSs when ${\displaystyle C_{c}^{\infty }\left(\Omega \times \Delta \right)}$  has its canonical LF topology.

Theorem^[1] Let Y be a Hausdorff locally convex space. For every continuous linear form ${\displaystyle y^{\prime }\in Y}$  and every ${\displaystyle f\in C^{\infty }\left(\Omega ;Y\right)}$ , let ${\displaystyle J_{y^{\prime }}(f):\Omega \to \mathbb {F} }$  be defined by ${\displaystyle J_{y^{\prime }}(f)(p)=y^{\prime }\left(f(p)\right)}$ . Then ${\displaystyle J_{y^{\prime }}:C^{\infty }\left(\Omega ;Y\right)toC^{\infty }\left(\Omega \right)}$  is a continuous linear map; and furthermore, the restriction ${\displaystyle J_{y^{\prime }}{\big \vert }_{C_{c}^{\infty }\left(\Omega ;Y\right)}:C_{c}^{\infty }\left(\Omega ;Y\right)\to C^{\infty }\left(\Omega \right)}$  is also continuous (where ${\displaystyle C_{c}^{\infty }\left(\Omega ;Y\right)}$  has the canonical LF topology).

Suppose henceforth that Y is a Hausdorff space. Given a function ${\displaystyle f\in C^{k}\left(\Omega \right)}$  and a vector ${\displaystyle y\in Y}$ , let ${\displaystyle f\otimes y}$  denote the map ${\displaystyle f\otimes y:\Omega \to Y}$  defined by ${\displaystyle \left(f\otimes y\right)(p)=f(p)y}$ . This defines a bilinear map ${\displaystyle \otimes :C^{k}\left(\Omega \right)\times Y\to C^{k}\left(\Omega ;Y\right)}$  into the space of functions whose image is contained in a finite-dimensional vector subspace of Y; this bilinear map turns this subspace into a tensor product of ${\displaystyle C^{k}\left(\Omega \right)}$  and Y, which we will denote by ${\displaystyle C^{k}\left(\Omega \right)\otimes Y}$ .^[1] Furthermore, if ${\displaystyle C_{c}^{k}\left(\Omega \right)\otimes Y}$  denotes the vector subspace of ${\displaystyle C^{k}\left(\Omega \right)\otimes Y}$  consisting of all functions with compact support, then ${\displaystyle C_{c}^{k}\left(\Omega \right)\otimes Y}$  is a tensor product of ${\displaystyle C_{c}^{k}\left(\Omega \right)}$  and Y.^[1]

If X is locally compact then ${\displaystyle C_{c}^{0}\left(\Omega \right)\otimes Y}$  is dense in ${\displaystyle C^{0}\left(\Omega ;X\right)}$  while if X is an open subset of ${\displaystyle \mathbb {R} ^{n}}$  then ${\displaystyle C_{c}^{\infty }\left(\Omega \right)\otimes Y}$  is dense in ${\displaystyle C^{k}\left(\Omega ;X\right)}$ .^[2]

Theorem^[2] If Y is a complete Hausdorff locally convex space, then ${\displaystyle C^{k}\left(\Omega ;Y\right)}$  is canonically isomorphic to the injective tensor product ${\displaystyle C^{k}\left(\Omega \right){\widehat {\otimes }}_{\epsilon }Y}$ .

• Fréchet derivative
• Injective tensor product

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