Injective tensor product

In functional analysis, an area of mathematics, the injective tensor product is a particular topological tensor product, a topological vector space (TVS) formed by equipping the tensor product of the underlying vector spaces of two TVSs with a compatible topology. It was introduced by Alexander Grothendieck and used by him to define nuclear spaces. Injective tensor products have applications outside of nuclear spaces: as described below, many constructions of TVSs, and in particular Banach spaces, as spaces of functions or sequences amount to injective tensor products of simpler spaces.

Definition

Let $X$ and $Y$ be locally convex topological vector spaces over $\mathbb {C}$ , with continuous dual spaces $X^{\prime }$ and $Y^{\prime }.$ A subscript $\sigma$ as in $X_{\sigma }^{\prime }$ denotes the weak-* topology. Although written in terms of complex TVSs, results described generally also apply to the real case.

The vector space $B\left(X_{\sigma }^{\prime },Y_{\sigma }^{\prime }\right)$ of continuous bilinear functionals $X_{\sigma }^{\prime }\times Y_{\sigma }^{\prime }\to \mathbb {C}$ is isomorphic to the (vector space) tensor product $X\otimes Y$ , as follows. For each simple tensor $x\otimes y$ in $X\otimes Y$ , there is a bilinear map $f\in B\left(X_{\sigma }^{\prime },Y_{\sigma }^{\prime }\right)$ , given by $f(\varphi ,\psi )=\varphi (x)\psi (y)$ . It can be shown that the map $x\otimes y\mapsto f$ , extended linearly to $X\otimes Y$ , is an isomorphism.

Let $X_{b}^{\prime },Y_{b}^{\prime }$ denote the respective dual spaces with the topology of bounded convergence. If $Z$ is a locally convex topological vector space, then ${\textstyle B\left(X_{\sigma }^{\prime },Y_{\sigma }^{\prime };Z\right)~\subseteq ~B\left(X_{b}^{\prime },Y_{b}^{\prime };Z\right)}$ . The topology of the injective tensor product is the topology induced from a certain topology on $B\left(X_{b}^{\prime },Y_{b}^{\prime };Z\right)$ , whose basic open sets are constructed as follows. For any equicontinuous subsets $G\subseteq X^{\prime }$ and $H\subseteq Y^{\prime }$ , and any neighborhood $N$ in $Z$ , define ${\mathcal {U}}(G,H,N)=\left\{b\in B\left(X_{b}^{\prime },Y_{b}^{\prime };Z\right)~:~b(G\times H)\subseteq N\right\}$ where every set $b(G\times H)$ is bounded in $Z,$ which is necessary and sufficient for the collection of all ${\mathcal {U}}(G,H,N)$ to form a locally convex TVS topology on ${\mathcal {B}}\left(X_{b}^{\prime },Y_{b}^{\prime };Z\right).$ ^[1] This topology is called the $\varepsilon$ -topology or injective topology. In the special case where $Z=\mathbb {C}$ is the underlying scalar field, $B\left(X_{\sigma }^{\prime },Y_{\sigma }^{\prime }\right)$ is the tensor product $X\otimes Y$ as above, and the topological vector space consisting of $X\otimes Y$ with the $\varepsilon$ -topology is denoted by $X\otimes _{\varepsilon }Y$ , and is not necessarily complete; its completion is the injective tensor product of $X$ and $Y$ and denoted by $X{\widehat {\otimes }}_{\varepsilon }Y$ .

If $X$ and $Y$ are normed spaces then $X\otimes _{\varepsilon }Y$ is normable. If $X$ and $Y$ are Banach spaces, then $X{\widehat {\otimes }}_{\varepsilon }Y$ is also. Its norm can be expressed in terms of the (continuous) duals of $X$ and $Y$ . Denoting the unit balls of the dual spaces $X^{*}$ and $Y^{*}$ by $B_{X^{*}}$ and $B_{Y^{*}}$ , the injective norm $\|u\|_{\varepsilon }$ of an element $u\in X\otimes Y$ is defined as $\|u\|_{\varepsilon }=\sup {\big \{}{\big |}\sum _{i}\varphi (x_{i})\psi (y_{i}){\big |}:\varphi \in B_{X^{*}},\psi \in B_{Y^{*}}{\big \}}$ where the supremum is taken over all expressions $u=\sum _{i}x_{i}\otimes y_{i}$ . Then the completion of $X\otimes Y$ under the injective norm is isomorphic as a topological vector space to $X{\widehat {\otimes }}_{\varepsilon }Y$ .^[2]

Basic properties

The map $(x,y)\mapsto x\otimes y:X\times Y\to X\otimes _{\varepsilon }Y$ is continuous.^[3]

Suppose that $u:X_{1}\to Y_{1}$ and $v:X_{2}\to Y_{2}$ are two linear maps between locally convex spaces. If both $u$ and $v$ are continuous then so is their tensor product $u\otimes v:X_{1}\otimes _{\varepsilon }X_{2}\to Y_{1}\otimes _{\varepsilon }Y_{2}$ . Moreover:

If $u$ and $v$ are both TVS-embeddings then so is $u{\widehat {\otimes }}_{\varepsilon }v:X_{1}{\widehat {\otimes }}_{\varepsilon }X_{2}\to Y_{1}{\widehat {\otimes }}_{\varepsilon }Y_{2}.$
If $X_{1}$ (resp. $Y_{1}$ ) is a linear subspace of $X_{2}$ (resp. $Y_{2}$ ) then $X_{1}\otimes _{\varepsilon }Y_{1}$ is canonically isomorphic to a linear subspace of $X_{2}\otimes _{\varepsilon }Y_{2}$ and $X_{1}{\widehat {\otimes }}_{\varepsilon }Y_{1}$ is canonically isomorphic to a linear subspace of $X_{2}{\widehat {\otimes }}_{\varepsilon }Y_{2}.$
There are examples of $u$ and $v$ such that both $u$ and $v$ are surjective homomorphisms but $u{\widehat {\otimes }}_{\varepsilon }v:X_{1}{\widehat {\otimes }}_{\varepsilon }X_{2}\to Y_{1}{\widehat {\otimes }}_{\varepsilon }Y_{2}$ is not a homomorphism.
If all four spaces are normed then $\|u\otimes v\|_{\varepsilon }=\|u\|\|v\|.$ ^[4]

Relation to projective tensor product

The projective topology or the $\pi$ -topology is the finest locally convex topology on $B\left(X_{\sigma }^{\prime },Y_{\sigma }^{\prime }\right)=X\otimes Y$ that makes continuous the canonical map $X\times Y\to X\otimes Y$ defined by sending $(x,y)\in X\times Y$ to the bilinear form $x\otimes y.$ When $X\otimes Y$ is endowed with this topology then it will be denoted by $X\otimes _{\pi }Y$ and called the projective tensor product of $X$ and $Y.$

The injective topology is always coarser than the projective topology, which is in turn coarser than the inductive topology (the finest locally convex TVS topology making $X\times Y\to X\otimes Y$ separately continuous).

The space $X\otimes _{\varepsilon }Y$ is Hausdorff if and only if both $X$ and $Y$ are Hausdorff. If $X$ and $Y$ are normed then $\|\theta \|_{\varepsilon }\leq \|\theta \|_{\pi }$ for all $\theta \in X\otimes Y$ , where $\|\cdot \|_{\pi }$ is the projective norm.^[5]

The injective and projective topologies both figure in Grothendieck's definition of nuclear spaces.^[6]

Duals of injective tensor products

The continuous dual space of $X\otimes _{\varepsilon }Y$ is a vector subspace of $B(X,Y)$ , denoted by $J(X,Y).$ The elements of $J(X,Y)$ are called integral forms on $X\times Y$ , a term justified by the following fact.

The dual $J(X,Y)$ of $X{\widehat {\otimes }}_{\varepsilon }Y$ consists of exactly those continuous bilinear forms $v$ on $X\times Y$ for which $v(x,y)=\int _{S\times T}\varphi (x)\psi (y)\,d\mu (\varphi ,\psi )$ for some closed, equicontinuous subsets $S$ and $T$ of $X_{\sigma }^{\prime }$ and $Y_{\sigma }^{\prime },$ respectively, and some Radon measure $\mu$ on the compact set $S\times T$ with total mass $\leq 1$ .^[7] In the case where $X,Y$ are Banach spaces, $S$ and $T$ can be taken to be the unit balls $B_{X^{*}}$ and $B_{Y^{*}}$ .^[8]

Furthermore, if $A$ is an equicontinuous subset of $J(X,Y)$ then the elements $v\in A$ can be represented with $S\times T$ fixed and $\mu$ running through a norm bounded subset of the space of Radon measures on $S\times T.$ ^[9]

Examples

For $X$ a Banach space, certain constructions related to $X$ in Banach space theory can be realized as injective tensor products. Let $c_{0}(X)$ be the space of sequences of elements of $X$ converging to $0$ , equipped with the norm $\|(x_{i})\|=\sup _{i}\|x_{i}\|_{X}$ . Let $\ell _{1}(X)$ be the space of unconditionally summable sequences in $X$ , equipped with the norm $\|(x_{i})\|=\sup {\big \{}\sum _{i=1}^{\infty }|\varphi (x_{i})|:\varphi \in B_{X^{*}}{\big \}}.$ Then $c_{0}(X)$ and $\ell _{1}(X)$ are Banach spaces, and isometrically $c_{0}(X)\cong c_{0}{\widehat {\otimes }}_{\varepsilon }X$ and $\ell _{1}(X)\cong \ell _{1}{\widehat {\otimes }}_{\varepsilon }X$ (where $c_{0},\,\ell _{1}$ are the classical sequence spaces).^[10] These facts can be generalized to the case where $X$ is a locally convex TVS.^[11]

If $H$ and $K$ are compact Hausdorff spaces, then $C(H\times K)\cong C(H){\widehat {\otimes }}_{\varepsilon }C(K)$ as Banach spaces, where $C(X)$ denotes the Banach space of continuous functions on $X$ .^[11]

Spaces of differentiable functions

Let $\Omega$ be an open subset of $\mathbb {R} ^{n}$ , let $Y$ be a complete, Hausdorff, locally convex topological vector space, and let $C^{k}(\Omega ;Y)$ be the space of $k$ -times continuously differentiable $Y$ -valued functions. Then $C^{k}(\Omega ;Y)\cong C^{k}(\Omega ){\widehat {\otimes }}_{\varepsilon }Y$ .

The Schwartz spaces ${\mathcal {L}}\left(\mathbb {R} ^{n}\right)$ can also be generalized to TVSs, as follows: let ${\mathcal {L}}\left(\mathbb {R} ^{n};Y\right)$ be the space of all $f\in C^{\infty }\left(\mathbb {R} ^{n};Y\right)$ such that for all pairs of polynomials $P$ and $Q$ in $n$ variables, $\left\{P(x)Q\left(\partial /\partial x\right)f(x):x\in \mathbb {R} ^{n}\right\}$ is a bounded subset of $Y.$ Topologize ${\mathcal {L}}\left(\mathbb {R} ^{n};Y\right)$ with the topology of uniform convergence over $\mathbb {R} ^{n}$ of the functions $P(x)Q\left(\partial /\partial x\right)f(x),$ as $P$ and $Q$ vary over all possible pairs of polynomials in $n$ variables. Then, ${\mathcal {L}}\left(\mathbb {R} ^{n};Y\right)\cong {\mathcal {L}}\left(\mathbb {R} ^{n}\right){\widehat {\otimes }}_{\varepsilon }Y.$ ^[11]

Notes

^ Trèves 2006, pp. 427–428.
^ Ryan 2002, p. 45.
^ Trèves 2006, p. 434.
^ Trèves 2006, p. 439–444.
^ Trèves 2006, p. 434–44.
^ Schaefer & Wolff 1999, p. 170.
^ Trèves 2006, pp. 500–502.
^ Ryan 2002, p. 58.
^ Schaefer & Wolff 1999, p. 168.
^ Ryan 2002, pp. 47–49.
^ ^a ^b ^c Trèves 2006, pp. 446–451.

References

Ryan, Raymond (2002). Introduction to tensor products of Banach spaces. London New York: Springer. ISBN 1-85233-437-1. OCLC 48092184.
Schaefer, Helmut H.; Wolff, Manfred P. (1999). Topological Vector Spaces. GTM. Vol. 8 (Second ed.). New York, NY: Springer New York Imprint Springer. ISBN 978-1-4612-7155-0. OCLC 840278135.
Trèves, François (2006) [1967]. Topological Vector Spaces, Distributions and Kernels. Mineola, N.Y.: Dover Publications. ISBN 978-0-486-45352-1. OCLC 853623322.

External links

Nuclear space at ncatlab

[FOOTNOTETrèves2006427–428-1] Trèves 2006, pp. 427–428.

[FOOTNOTERyan200245-2] Ryan 2002, p. 45.

[FOOTNOTETrèves2006434-3] Trèves 2006, p. 434.

[FOOTNOTETrèves2006439–444-4] Trèves 2006, p. 439–444.

[FOOTNOTETrèves2006434–44-5] Trèves 2006, p. 434–44.

[FOOTNOTESchaeferWolff1999170-6] Schaefer & Wolff 1999, p. 170.

[FOOTNOTETrèves2006500–502-7] Trèves 2006, pp. 500–502.

[FOOTNOTERyan200258-8] Ryan 2002, p. 58.

[FOOTNOTESchaeferWolff1999168-9] Schaefer & Wolff 1999, p. 168.

[FOOTNOTERyan200247–49-10] Ryan 2002, pp. 47–49.

[FOOTNOTETrèves2006446–451-11] Trèves 2006, pp. 446–451.

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Topological tensor products and nuclear spaces
Basic concepts	Auxiliary normed spaces Nuclear space Tensor product Topological tensor product of Hilbert spaces
Topologies	Inductive tensor product Projective tensor product
Operators/Maps	Fredholm determinant Fredholm kernel Hilbert–Schmidt operator Hypocontinuity Integral Nuclear between Banach spaces Trace class
Theorems	Grothendieck trace theorem Schwartz kernel theorem