Barrelled space

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Short description: Type of topological vector space

In functional analysis and related areas of mathematics, a barrelled space (also written barreled space) is a topological vector space (TVS) for which every barrelled set in the space is a neighbourhood for the zero vector. A barrelled set or a barrel in a topological vector space is a set that is convex, balanced, absorbing, and closed. Barrelled spaces are studied because a form of the Banach–Steinhaus theorem still holds for them. Barrelled spaces were introduced by Bourbaki (1950).

Barrels

A convex and balanced subset of a real or complex vector space is called a disk and it is said to be disked, absolutely convex, or convex balanced.

A barrel or a barrelled set in a topological vector space (TVS) is a subset that is a closed absorbing disk; that is, a barrel is a convex, balanced, closed, and absorbing subset.

Every barrel must contain the origin. If dimX2 and if S is any subset of X, then S is a convex, balanced, and absorbing set of X if and only if this is all true of SY in Y for every 2-dimensional vector subspace Y; thus if dimX>2 then the requirement that a barrel be a closed subset of X is the only defining property that does not depend solely on 2 (or lower)-dimensional vector subspaces of X.

If X is any TVS then every closed convex and balanced neighborhood of the origin is necessarily a barrel in X (because every neighborhood of the origin is necessarily an absorbing subset). In fact, every locally convex topological vector space has a neighborhood basis at its origin consisting entirely of barrels. However, in general, there might exist barrels that are not neighborhoods of the origin; "barrelled spaces" are exactly those TVSs in which every barrel is necessarily a neighborhood of the origin. Every finite dimensional topological vector space is a barrelled space so examples of barrels that are not neighborhoods of the origin can only be found in infinite dimensional spaces.

Examples of barrels and non-barrels

The closure of any convex, balanced, and absorbing subset is a barrel. This is because the closure of any convex (respectively, any balanced, any absorbing) subset has this same property.

A family of examples: Suppose that X is equal to (if considered as a complex vector space) or equal to 2 (if considered as a real vector space). Regardless of whether X is a real or complex vector space, every barrel in X is necessarily a neighborhood of the origin (so X is an example of a barrelled space). Let R:[0,2π)(0,] be any function and for every angle θ[0,2π), let Sθ denote the closed line segment from the origin to the point R(θ)eiθ. Let S:=θ[0,2π)Sθ. Then S is always an absorbing subset of 2 (a real vector space) but it is an absorbing subset of (a complex vector space) if and only if it is a neighborhood of the origin. Moreover, S is a balanced subset of 2 if and only if R(θ)=R(π+θ) for every 0θ<π (if this is the case then R and S are completely determined by R's values on [0,π)) but S is a balanced subset of if and only it is an open or closed ball centered at the origin (of radius 0<r). In particular, barrels in are exactly those closed balls centered at the origin with radius in (0,]. If R(θ):=2πθ then S is a closed subset that is absorbing in 2 but not absorbing in , and that is neither convex, balanced, nor a neighborhood of the origin in X. By an appropriate choice of the function R, it is also possible to have S be a balanced and absorbing subset of 2 that is neither closed nor convex. To have S be a balanced, absorbing, and closed subset of 2 that is neither convex nor a neighborhood of the origin, define R on [0,π) as follows: for 0θ<π, let R(θ):=πθ (alternatively, it can be any positive function on [0,π) that is continuously differentiable, which guarantees that limθ0R(θ)=R(0)>0 and that S is closed, and that also satisfies limθπR(θ)=0, which prevents S from being a neighborhood of the origin) and then extend R to [π,2π) by defining R(θ):=R(θπ), which guarantees that S is balanced in 2.

Properties of barrels

  • In any topological vector space (TVS) X, every barrel in X absorbs every compact convex subset of X.[1]
  • In any locally convex Hausdorff TVS X, every barrel in X absorbs every convex bounded complete subset of X.[1]
  • If X is locally convex then a subset H of X is σ(X,X)-bounded if and only if there exists a barrel B in X such that HB.[1]
  • Let (X,Y,b) be a pairing and let ν be a locally convex topology on X consistent with duality. Then a subset B of X is a barrel in (X,ν) if and only if B is the polar of some σ(Y,X,b)-bounded subset of Y.[1]
  • Suppose M is a vector subspace of finite codimension in a locally convex space X and BM. If B is a barrel (resp. bornivorous barrel, bornivorous disk) in M then there exists a barrel (resp. bornivorous barrel, bornivorous disk) C in X such that B=CM.[2]

Characterizations of barreled spaces

Denote by L(X;Y) the space of continuous linear maps from X into Y.

If (X,τ) is a Hausdorff topological vector space (TVS) with continuous dual space X then the following are equivalent:

  1. X is barrelled.
  2. Definition: Every barrel in X is a neighborhood of the origin.
    • This definition is similar to a characterization of Baire TVSs proved by Saxon [1974], who proved that a TVS Y with a topology that is not the indiscrete topology is a Baire space if and only if every absorbing balanced subset is a neighborhood of some point of Y (not necessarily the origin).[2]
  3. For any Hausdorff TVS Y every pointwise bounded subset of L(X;Y) is equicontinuous.[3]
  4. For any F-space Y every pointwise bounded subset of L(X;Y) is equicontinuous.[3]
  5. Every closed linear operator from X into a complete metrizable TVS is continuous.[4]
  6. Every Hausdorff TVS topology ν on X that has a neighborhood basis of the origin consisting of τ-closed set is course than τ.[5]

If (X,τ) is locally convex space then this list may be extended by appending:

  1. There exists a TVS Y not carrying the indiscrete topology (so in particular, Y{0}) such that every pointwise bounded subset of L(X;Y) is equicontinuous.[2]
  2. For any locally convex TVS Y, every pointwise bounded subset of L(X;Y) is equicontinuous.[2]
    • It follows from the above two characterizations that in the class of locally convex TVS, barrelled spaces are exactly those for which the uniform boundedness principal holds.
  3. Every σ(X,X)-bounded subset of the continuous dual space X is equicontinuous (this provides a partial converse to the Banach-Steinhaus theorem).[2][6]
  4. X carries the strong dual topology β(X,X).[2]
  5. Every lower semicontinuous seminorm on X is continuous.[2]
  6. Every linear map F:XY into a locally convex space Y is almost continuous.[2]
    • A linear map F:XY is called almost continuous if for every neighborhood V of the origin in Y, the closure of F1(V) is a neighborhood of the origin in X.
  7. Every surjective linear map F:YX from a locally convex space Y is almost open.[2]
    • This means that for every neighborhood V of 0 in Y, the closure of F(V) is a neighborhood of 0 in X.
  8. If ω is a locally convex topology on X such that (X,ω) has a neighborhood basis at the origin consisting of τ-closed sets, then ω is weaker than τ.[2]

If X is a Hausdorff locally convex space then this list may be extended by appending:

  1. Closed graph theorem: Every closed linear operator F:XY into a Banach space Y is continuous.[7]
  2. For every subset A of the continuous dual space of X, the following properties are equivalent: A is[6]
    1. equicontinuous;
    2. relatively weakly compact;
    3. strongly bounded;
    4. weakly bounded.
  3. The 0-neighborhood bases in X and the fundamental families of bounded sets in Xβ correspond to each other by polarity.[6]

If X is metrizable topological vector space then this list may be extended by appending:

  1. For any complete metrizable TVS Y every pointwise bounded sequence in L(X;Y) is equicontinuous.[3]

If X is a locally convex metrizable topological vector space then this list may be extended by appending:

  1. (Property S): The weak* topology on X is sequentially complete.[8]
  2. (Property C): Every weak* bounded subset of X is σ(X,X)-relatively countably compact.[8]
  3. (𝜎-barrelled): Every countable weak* bounded subset of X is equicontinuous.[8]
  4. (Baire-like): X is not the union of an increase sequence of nowhere dense disks.[8]

Examples and sufficient conditions

Each of the following topological vector spaces is barreled:

  1. TVSs that are Baire space.
    • Consequently, every topological vector space that is of the second category in itself is barrelled.
  2. F-spaces, Fréchet spaces, Banach spaces, and Hilbert spaces.
    • However, there exist normed vector spaces that are not barrelled. For example, if the Lp-space L2([0,1]) is topologized as a subspace of L1([0,1]), then it is not barrelled.
  3. Complete pseudometrizable TVSs.[9]
    • Consequently, every finite-dimensional TVS is barrelled.
  4. Montel spaces.
  5. Strong dual spaces of Montel spaces (since they are necessarily Montel spaces).
  6. A locally convex quasi-barrelled space that is also a σ-barrelled space.[10]
  7. A sequentially complete quasibarrelled space.
  8. A quasi-complete Hausdorff locally convex infrabarrelled space.[2]
    • A TVS is called quasi-complete if every closed and bounded subset is complete.
  9. A TVS with a dense barrelled vector subspace.[2]
    • Thus the completion of a barreled space is barrelled.
  10. A Hausdorff locally convex TVS with a dense infrabarrelled vector subspace.[2]
    • Thus the completion of an infrabarrelled Hausdorff locally convex space is barrelled.[2]
  11. A vector subspace of a barrelled space that has countable codimensional.[2]
    • In particular, a finite codimensional vector subspace of a barrelled space is barreled.
  12. A locally convex ultrabarelled TVS.[11]
  13. A Hausdorff locally convex TVS X such that every weakly bounded subset of its continuous dual space is equicontinuous.[12]
  14. A locally convex TVS X such that for every Banach space B, a closed linear map of X into B is necessarily continuous.[13]
  15. A product of a family of barreled spaces.[14]
  16. A locally convex direct sum and the inductive limit of a family of barrelled spaces.[15]
  17. A quotient of a barrelled space.[16][15]
  18. A Hausdorff sequentially complete quasibarrelled boundedly summing TVS.[17]
  19. A locally convex Hausdorff reflexive space is barrelled.

Counter examples

  • A barrelled space need not be Montel, complete, metrizable, unordered Baire-like, nor the inductive limit of Banach spaces.
  • Not all normed spaces are barrelled. However, they are all infrabarrelled.[2]
  • A closed subspace of a barreled space is not necessarily countably quasi-barreled (and thus not necessarily barrelled).[18]
  • There exists a dense vector subspace of the Fréchet barrelled space that is not barrelled.[2]
  • There exist complete locally convex TVSs that are not barrelled.[2]
  • The finest locally convex topology on an infinite-dimensional vector space is a Hausdorff barrelled space that is a meagre subset of itself (and thus not a Baire space).[2]

Properties of barreled spaces

Banach–Steinhaus generalization

The importance of barrelled spaces is due mainly to the following results.

Theorem[19] — Let X be a barrelled TVS and Y be a locally convex TVS. Let H be a subset of the space L(X;Y) of continuous linear maps from X into Y. The following are equivalent:

  1. H is bounded for the topology of pointwise convergence;
  2. H is bounded for the topology of bounded convergence;
  3. H is equicontinuous.

The Banach-Steinhaus theorem is a corollary of the above result.[20] When the vector space Y consists of the complex numbers then the following generalization also holds.

Theorem[21] — If X is a barrelled TVS over the complex numbers and H is a subset of the continuous dual space of X, then the following are equivalent:

  1. H is weakly bounded;
  2. H is strongly bounded;
  3. H is equicontinuous;
  4. H is relatively compact in the weak dual topology.

Recall that a linear map F:XY is called closed if its graph is a closed subset of X×Y.

Closed Graph Theorem[22] — Every closed linear operator from a Hausdorff barrelled TVS into a complete metrizable TVS is continuous.

Other properties

  • Every Hausdorff barrelled space is quasi-barrelled.[23]
  • A linear map from a barrelled space into a locally convex space is almost continuous.
  • A linear map from a locally convex space onto a barrelled space is almost open.
  • A separately continuous bilinear map from a product of barrelled spaces into a locally convex space is hypocontinuous.[24]
  • A linear map with a closed graph from a barreled TVS into a Br-complete TVS is necessarily continuous.[13]

See also

References

Bibliography