Projective tensor product

In functional analysis, an area of mathematics, the projective tensor product of two locally convex topological vector spaces is a natural topological vector space structure on their tensor product. Namely, given locally convex topological vector spaces and , the projective topology, or π-topology, on is the strongest topology which makes a locally convex topological vector space such that the canonical map (from to ) is continuous. When equipped with this topology, is denoted and called the projective tensor product of and .

Definitions

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Let   and   be locally convex topological vector spaces. Their projective tensor product   is the unique locally convex topological vector space with underlying vector space   having the following universal property:[1]

For any locally convex topological vector space  , if   is the canonical map from the vector space of bilinear maps   to the vector space of linear maps  , then the image of the restriction of   to the continuous bilinear maps is the space of continuous linear maps  .

When the topologies of   and   are induced by seminorms, the topology of   is induced by seminorms constructed from those on   and   as follows. If   is a seminorm on  , and   is a seminorm on  , define their tensor product   to be the seminorm on   given by   for all   in  , where   is the balanced convex hull of the set  . The projective topology on   is generated by the collection of such tensor products of the seminorms on   and  .[2][1] When   and   are normed spaces, this definition applied to the norms on   and   gives a norm, called the projective norm, on   which generates the projective topology.[3]

Properties

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Throughout, all spaces are assumed to be locally convex. The symbol   denotes the completion of the projective tensor product of   and  .

  • If   and   are both Hausdorff then so is  ;[3] if   and   are Fréchet spaces then   is barelled.[4]
  • For any two continuous linear operators   and  , their tensor product (as linear maps)   is continuous.[5]
  • In general, the projective tensor product does not respect subspaces (e.g. if   is a vector subspace of   then the TVS   has in general a coarser topology than the subspace topology inherited from  ).[6]
  • If   and   are complemented subspaces of   and   respectively, then   is a complemented vector subspace of   and the projective norm on   is equivalent to the projective norm on   restricted to the subspace  . Furthermore, if   and   are complemented by projections of norm 1, then   is complemented by a projection of norm 1.[6]
  • Let   and   be vector subspaces of the Banach spaces   and  , respectively. Then   is a TVS-subspace of   if and only if every bounded bilinear form on   extends to a continuous bilinear form on   with the same norm.[7]

Completion

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In general, the space   is not complete, even if both   and   are complete (in fact, if   and   are both infinite-dimensional Banach spaces then   is necessarily not complete[8]). However,   can always be linearly embedded as a dense vector subspace of some complete locally convex TVS, which is generally denoted by  .

The continuous dual space of   is the same as that of  , namely, the space of continuous bilinear forms  .[9]

Grothendieck's representation of elements in the completion

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In a Hausdorff locally convex space   a sequence   in   is absolutely convergent if   for every continuous seminorm   on  [10] We write   if the sequence of partial sums   converges to   in  [10]

The following fundamental result in the theory of topological tensor products is due to Alexander Grothendieck.[11]

Theorem — Let   and   be metrizable locally convex TVSs and let   Then   is the sum of an absolutely convergent series   where   and   and   are null sequences in   and   respectively.

The next theorem shows that it is possible to make the representation of   independent of the sequences   and  

Theorem[12] — Let   and   be Fréchet spaces and let   (resp.  ) be a balanced open neighborhood of the origin in   (resp. in  ). Let   be a compact subset of the convex balanced hull of   There exists a compact subset   of the unit ball in   and sequences   and   contained in   and   respectively, converging to the origin such that for every   there exists some   such that  

Topology of bi-bounded convergence

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Let   and   denote the families of all bounded subsets of   and   respectively. Since the continuous dual space of   is the space of continuous bilinear forms   we can place on   the topology of uniform convergence on sets in   which is also called the topology of bi-bounded convergence. This topology is coarser than the strong topology on  , and in (Grothendieck 1955), Alexander Grothendieck was interested in when these two topologies were identical. This is equivalent to the problem: Given a bounded subset   do there exist bounded subsets   and   such that   is a subset of the closed convex hull of  ?

Grothendieck proved that these topologies are equal when   and   are both Banach spaces or both are DF-spaces (a class of spaces introduced by Grothendieck[13]). They are also equal when both spaces are Fréchet with one of them being nuclear.[9]

Strong dual and bidual

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Let   be a locally convex topological vector space and let   be its continuous dual space. Alexander Grothendieck characterized the strong dual and bidual for certain situations:

Theorem[14] (Grothendieck) — Let   and   be locally convex topological vector spaces with   nuclear. Assume that both   and   are Fréchet spaces, or else that they are both DF-spaces. Then, denoting strong dual spaces with a subscripted  :

  1. The strong dual of   can be identified with  ;
  2. The bidual of   can be identified with  ;
  3. If   is reflexive then   (and hence  ) is a reflexive space;
  4. Every separately continuous bilinear form on   is continuous;
  5. Let   be the space of bounded linear maps from   to  . Then, its strong dual can be identified with   so in particular if   is reflexive then so is  

Examples

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  • For   a measure space, let   be the real Lebesgue space  ; let   be a real Banach space. Let   be the completion of the space of simple functions  , modulo the subspace of functions   whose pointwise norms, considered as functions  , have integral   with respect to  . Then   is isometrically isomorphic to  .[15]

See also

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Citations

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  1. ^ a b Trèves 2006, p. 438.
  2. ^ Trèves 2006, p. 435.
  3. ^ a b Trèves 2006, p. 437.
  4. ^ Trèves 2006, p. 445.
  5. ^ Trèves 2006, p. 439.
  6. ^ a b Ryan 2002, p. 18.
  7. ^ Ryan 2002, p. 24.
  8. ^ Ryan 2002, p. 43.
  9. ^ a b Schaefer & Wolff 1999, p. 173.
  10. ^ a b Schaefer & Wolff 1999, p. 120.
  11. ^ Schaefer & Wolff 1999, p. 94.
  12. ^ Trèves 2006, pp. 459–460.
  13. ^ Schaefer & Wolff 1999, p. 154.
  14. ^ Schaefer & Wolff 1999, pp. 175–176.
  15. ^ Schaefer & Wolff 1999, p. 95.

References

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  • 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.

Further reading

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  • Diestel, Joe (2008). The metric theory of tensor products : Grothendieck's résumé revisited. Providence, R.I: American Mathematical Society. ISBN 978-0-8218-4440-3. OCLC 185095773.
  • Grothendieck, Alexander (1955). "Produits Tensoriels Topologiques et Espaces Nucléaires" [Topological Tensor Products and Nuclear Spaces]. Memoirs of the American Mathematical Society Series (in French). 16. Providence: American Mathematical Society. ISBN 978-0-8218-1216-7. MR 0075539. OCLC 1315788.
  • Grothendieck, Grothendieck (1966). Produits tensoriels topologiques et espaces nucléaires (in French). Providence: American Mathematical Society. ISBN 0-8218-1216-5. OCLC 1315788.
  • Pietsch, Albrecht (1972). Nuclear locally convex spaces. Berlin, New York: Springer-Verlag. ISBN 0-387-05644-0. OCLC 539541.
  • Wong (1979). Schwartz spaces, nuclear spaces, and tensor products. Berlin New York: Springer-Verlag. ISBN 3-540-09513-6. OCLC 5126158.
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