topological tensor product

One of the original motivations for topological tensor products $\backslash hat\{\backslash otimes\}$ is the fact that tensor products of the spaces of smooth real-valued functions on $\backslash R^n$ do not behave as expected. There is an injection

:$C^\backslash infty(\backslash R^n)\; \backslash otimes\; C^\backslash infty(\backslash R^m)\; \backslash hookrightarrow\; C^\backslash infty(\backslash R^\{n+m\})$

but this is not an isomorphism. For example, the function $f(x,y)\; =\; e^\{xy\}$ cannot be expressed as a finite linear combination of smooth functions in $C^\backslash infty(\backslash R\_x)\backslash otimes\; C^\backslash infty(\backslash R\_y).${{Cite web| url= https://math.stackexchange.com/a/2244646/251222|title=What is an example of a smooth function in C∞(R2) which is not contained in C∞(R)⊗C∞(R) }} We only get an isomorphism after constructing the topological tensor product; i.e.,

:$C^\backslash infty(\backslash R^n)\; \backslash mathop\{\backslash hat\{\backslash otimes\}\}\; C^\backslash infty(\backslash R^m)\; \backslash cong\; C^\backslash infty(\backslash R^\{n+m\}).$

This article first details the construction in the Banach space case. The space $C^\backslash infty(\backslash R^n)$ is not a Banach space and further cases are discussed at the end.

{{Main|Tensor product of Hilbert spaces}}

The algebraic tensor product of two Hilbert spaces A and B has a natural positive definite sesquilinear form (scalar product) induced by the sesquilinear forms of A and B. So in particular it has a natural positive definite quadratic form, and the corresponding completion is a Hilbert space A ⊗ B, called the (Hilbert space) tensor product of A and B.

If the vectors a_i and b_j run through orthonormal bases of A and B, then the vectors a_i⊗b_j form an orthonormal basis of A ⊗ B.

We shall use the notation from {{harv|Ryan|2002}} in this section. The obvious way to define the tensor product of two Banach spaces $A$ and $B$ is to copy the method for Hilbert spaces: define a norm on the algebraic tensor product, then take the completion in this norm. The problem is that there is more than one natural way to define a norm on the tensor product.

If $A$ and $B$ are Banach spaces the algebraic tensor product of $A$ and $B$ means the tensor product of $A$ and $B$ as vector spaces and is denoted by $A\; \backslash otimes\; B.$ The algebraic tensor product $A\; \backslash otimes\; B$ consists of all finite sums

$$x\; =\; \backslash sum\_\{i=1\}^n\; a\_i\; \backslash otimes\; b\_i,$$

where $n$ is a natural number depending on $x$ and $a\_i\; \backslash in\; A$ and $b\_i\; \backslash in\; B$ for

$i\; =\; 1,\; \backslash ldots,\; n.$

When $A$ and $B$ are Banach spaces, a {{visible anchor|crossnorm}} (or {{visible anchor|cross norm}}) $p$ on the algebraic tensor product $A\; \backslash otimes\; B$ is a norm satisfying the conditions

$$p(a\; \backslash otimes\; b)\; =\; \backslash |a\backslash |\; \backslash |b\backslash |,$$

$$p\text{'}(a\text{'}\; \backslash otimes\; b\text{'})\; =\; \backslash |a\text{'}\backslash |\; \backslash |b\text{'}\backslash |.$$

Here $a^\{\backslash prime\}$ and $b^\{\backslash prime\}$ are elements of the topological dual spaces of $A$ and $B,$ respectively, and $p^\{\backslash prime\}$ is the dual norm of $p.$ The term {{visible anchor|reasonable crossnorm}} is also used for the definition above.

There is a cross norm $\backslash pi$ called the projective cross norm, given by

$$\backslash pi(x)\; =\; \backslash inf\; \backslash left\backslash \{\; \backslash sum\_\{i=1\}^n\; \backslash |a\_i\backslash |\; \backslash |b\_i\backslash |\; :\; x\; =\; \backslash sum\_\{i=1\}^n\; a\_i\; \backslash otimes\; b\_i\; \backslash right\backslash \},$$

where $x\; \backslash in\; A\; \backslash otimes\; B.$

It turns out that the projective cross norm agrees with the largest cross norm {{harv|Ryan|2002|pp=15-16}}.

There is a cross norm $\backslash varepsilon$ called the injective cross norm, given by

$$\backslash varepsilon(x)\; =\; \backslash sup\; \backslash left\backslash \{\backslash left|(a\text{'}\backslash otimes\; b\text{'})(x)\backslash right|\; :\; a\text{'}\; \backslash in\; A\text{'},\; b\text{'}\; \backslash in\; B\text{'},\; \backslash |a\text{'}\backslash |\; =\; \backslash |b\text{'}\backslash |\; =\; 1\backslash right\backslash \}$$

where $x\; \backslash in\; A\; \backslash otimes\; B.$ Here $A^\{\backslash prime\}$ and $B^\{\backslash prime\}$ denote the topological duals of $A$ and $B,$ respectively.

Note hereby that the injective cross norm is only in some reasonable sense the "smallest".

The completions of the algebraic tensor product in these two norms are called the projective and injective tensor products, and are denoted by $A\; \backslash operatorname\{\backslash hat\{\backslash otimes\}\}\_\backslash pi\; B$ and $A\; \backslash operatorname\{\backslash hat\{\backslash otimes\}\}\_\backslash varepsilon\; B.$

When $A$ and $B$ are Hilbert spaces, the norm used for their Hilbert space tensor product is not equal to either of these norms in general. Some authors denote it by $\backslash sigma,$ so the Hilbert space tensor product in the section above would be $A\; \backslash operatorname\{\backslash hat\{\backslash otimes\}\}\_\backslash sigma\; B.$

A {{visible anchor|uniform crossnorm}} $\backslash alpha$ is an assignment to each pair $(X,\; Y)$ of Banach spaces of a reasonable crossnorm on $X\; \backslash otimes\; Y$ so that if $X,\; W,\; Y,\; Z$ are arbitrary Banach spaces then for all (continuous linear) operators $S\; :\; X\; \backslash to\; W$ and $T\; :\; Y\; \backslash to\; Z$ the operator $S\; \backslash otimes\; T\; :\; X\; \backslash otimes\_\backslash alpha\; Y\; \backslash to\; W\; \backslash otimes\_\backslash alpha\; Z$ is continuous and $\backslash |S\; \backslash otimes\; T\backslash |\; \backslash leq\; \backslash |S\backslash |\; \backslash |T\backslash |.$ If $A$ and $B$ are two Banach spaces and $\backslash alpha$ is a uniform cross norm then $\backslash alpha$ defines a reasonable cross norm on the algebraic tensor product $A\; \backslash otimes\; B.$ The normed linear space obtained by equipping $A\; \backslash otimes\; B$ with that norm is denoted by $A\; \backslash otimes\_\backslash alpha\; B.$ The completion of $A\; \backslash otimes\_\backslash alpha\; B,$ which is a Banach space, is denoted by $A\; \backslash operatorname\{\backslash hat\{\backslash otimes\}\}\_\backslash alpha\; B.$ The value of the norm given by $\backslash alpha$ on $A\; \backslash otimes\; B$ and on the completed tensor product $A\; \backslash operatorname\{\backslash hat\{\backslash otimes\}\}\_\backslash alpha\; B$ for an element $x$ in $A\; \backslash operatorname\{\backslash hat\{\backslash otimes\}\}\_\backslash alpha\; B$ (or $A\; \backslash otimes\_\backslash alpha\; B$) is denoted by $\backslash alpha\_\{A,B\}(x)\; \backslash text\{\; or\; \}\; \backslash alpha(x).$

A uniform crossnorm $\backslash alpha$ is said to be {{visible anchor|finitely generated}} if, for every pair $(X,\; Y)$ of Banach spaces and every $u\; \backslash in\; X\; \backslash otimes\; Y,$

A uniform crossnorm $\backslash alpha$ is {{visible anchor|cofinitely generated}} if, for every pair $(X,\; Y)$ of Banach spaces and every $u\; \backslash in\; X\; \backslash otimes\; Y,$

A {{visible anchor|tensor norm}} is defined to be a finitely generated uniform crossnorm. The projective cross norm $\backslash pi$ and the injective cross norm $\backslash varepsilon$ defined above are tensor norms and they are called the projective tensor norm and the injective tensor norm, respectively.

If $A$ and $B$ are arbitrary Banach spaces and $\backslash alpha$ is an arbitrary uniform cross norm then

$$\backslash varepsilon\_\{A,B\}(x)\; \backslash leq\; \backslash alpha\_\{A,B\}(x)\; \backslash leq\; \backslash pi\_\{A,B\}(x).$$

{{See also|Injective tensor product|Projective tensor product}}

The topologies of locally convex topological vector spaces $A$ and $B$ are given by families of seminorms. For each choice of seminorm on $A$ and on $B$ we can define the corresponding family of cross norms on the algebraic tensor product $A\backslash otimes\; B,$ and by choosing one cross norm from each family we get some cross norms on $A\backslash otimes\; B,$ defining a topology. There are in general an enormous number of ways to do this. The two most important ways are to take all the projective cross norms, or all the injective cross norms. The completions of the resulting topologies on $A\backslash otimes\; B$ are called the projective and injective tensor products, and denoted by $A\backslash otimes\_\{\backslash gamma\}\; B$ and $A\backslash otimes\_\{\backslash lambda\}\; B.$ There is a natural map from $A\backslash otimes\_\{\backslash gamma\}\; B$ to $A\backslash otimes\_\{\backslash lambda\}\; B.$

If $A$ or $B$ is a nuclear space then the natural map from $A\backslash otimes\_\{\backslash gamma\}\; B$ to $A\backslash otimes\_\{\backslash lambda\}\; B$ is an isomorphism. Roughly speaking, this means that if $A$ or $B$ is nuclear, then there is only one sensible tensor product of $A$ and $B$.

This property characterizes nuclear spaces.

• {{annotated link|Fréchet space}}
• {{annotated link|Fredholm kernel}}
• {{annotated link|Inductive tensor product}}
• {{annotated link|Projective topology}}

{{reflist}}

• {{citation|last=Ryan|first=R.A.|title=Introduction to Tensor Products of Banach Spaces|publisher=Springer|publication-place=New York| year=2002}}.
• {{citation|first=A.|last=Grothendieck|authorlink=Alexander Grothendieck|title=Produits tensoriels topologiques et espaces nucléaires| journal=Memoirs of the American Mathematical Society|volume=16|year=1955}}.

{{Functional analysis}}

{{Topological tensor products and nuclear spaces}}

Category:Operator theory

Category:Topological vector spaces

Category:Hilbert spaces

Category:Tensors