Bornological space

In mathematics, particularly in functional analysis, a bornological space is a type of space which, in some sense, possesses the minimum amount of structure needed to address questions of boundedness of sets and functions, in the same way that a topological space possesses the minimum amount of structure needed to address questions of continuity. Bornological spaces were first studied by Mackey. The name was coined by Bourbaki.

Bornological sets

A bornology on a set X is a collection B of subsets of X such that

Elements of the collection B are usually called bounded sets. The pair (X, B) is called a bornological set.

A base of the bornology B is a subset B0 of B such that each element of B is a subset of an element of B0.

Examples

Bounded maps

If B1 and B2 are two bornologies over the spaces X and Y, respectively, and if f : X Y is a function, then we say that f is a bounded map if it maps B1-bounded sets in X to B2-bounded sets in Y. If in addition f is a bijection and f^{-1} is also bounded then we say that f is a bornological isomorphism.

Examples:

Theorems:

Vector bornologies

If X is a vector space over a field K and then a vector bornology on X is a bornology B on X that is stable under vector addition, scalar multiplication, and the formation of balanced hulls (i.e. if the sum of two bounded sets is bounded, etc.). If in addition B is stable under the formation of convex hulls (i.e. the convex hull of a bounded set is bounded) then B is called a convex vector bornology. And if the only bounded subspace of X is the trivial subspace (i.e. the space consisting only of 0) then it is called separated. A subset A of B is called bornivorous if it absorbs every bounded set. In a vector bornology, A is bornivorous if it absorbs every bounded balanced set and in a convex vector bornology A is bornivorous if it absorbs every bounded disk.

Bornology of a topological vector space

Every topological vector space X gives a bornology on X by defining a subset B ⊆ X to be bounded (or von-Neumann bounded), if and only if for all open sets U ⊆ X containing zero there exists a r > 0 with B ⊆ r U. If X is a locally convex topological vector space then B ⊆ X is bounded if and only if all continuous semi-norms on X are bounded on B.

The set of all bounded subsets of X is called the bornology or the Von-Neumann bornology of X.

Induced topology

Suppose that we start with a vector space X and convex vector bornology B on X. If we let T denote the collection of all sets that are convex, balanced, and bornivorous then T forms neighborhood basis at 0 for a locally convex topology on X that is compatible with the vector space structure of X.

Bornological spaces

In functional analysis, a bornological space is a locally convex topological vector space whose topology can be recovered from its bornology in a natural way. Explicitly, a Hausdorff locally convex space X with topology \tau and continuous dual X' is called a bornological space if any one of the following equivalent conditions holds:

where a subset A of X is called sequentially open if every sequence converging to 0 eventually belongs to A.

Examples

The following topological vector spaces are all bornological:

Properties

Banach disks

Suppose that X is a topological vector space. Then we say that a subset D of X is a disk if it is convex and balanced. The disk D is absorbing in the space span(D) and so its Minkowski functional forms a seminorm on this space, which is denoted by \mu_D or by pD. When we give span(D) the topology induced by this seminorm, we denote the resulting topological vector space by X_D. A basis of neighborhoods of 0 of this space consists of all sets of the form r D where r ranges over all positive real numbers. If D is Von-Neuman bounded in X then the (normed) topology of XD will be finer than the subspace topology that X induces on this set.

This space is not necessarily Hausdorff as is the case, for instance, if we let X = \mathbb{R}^2 and D be the x-axis. However, if D is a bounded disk and if X is Hausdorff, then \mu_D is a norm and XD is a normed space. If D is a bounded sequentially complete disk and X is Hausdorff, then the space XD is a Banach space. A bounded disk in X for which XD is a Banach space is called a Banach disk, infracomplete, or a bounded completant.

Properties

Suppose that X is a locally convex Hausdorff space. If D is a bounded Banach disk in X and T is a barrel in X then T absorbs D (i.e. there is a number r > 0 such that D ⊆ r T).

Examples

Ultrabornological spaces

A disk in a topological vector space X is called infrabornivorous if it absorbs all Banach disks. If X is locally convex and Hausdorff, then a disk is infrabornivorous if and only if it absorbs all compact disks. A locally convex space is called ultrabornological if any of the following conditions hold:

Properties

See also

References

    This article is issued from Wikipedia - version of the Wednesday, April 20, 2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.