Bornology Explained

In mathematics, especially functional analysis, a bornology on a set X is a collection of subsets of X satisfying axioms that generalize the notion of boundedness. One of the key motivations behind bornologies and bornological analysis is the fact that bornological spaces provide a convenient setting for homological algebra in functional analysis. This is because^[1] ^{pg 9} the category of bornological spaces is additive, complete, cocomplete, and has a tensor product adjoint to an internal hom, all necessary components for homological algebra.

History

Bornology originates from functional analysis. There are two natural ways of studying the problems of functional analysis: one way is to study notions related to topologies (vector topologies, continuous operators, open/compact subsets, etc.) and the other is to study notions related to boundedness (vector bornologies, bounded operators, bounded subsets, etc.).

For normed spaces, from which functional analysis arose, topological and bornological notions are distinct but complementary and closely related. For example, the unit ball centered at the origin is both a neighborhood of the origin and a bounded subset. Furthermore, a subset of a normed space is a neighborhood of the origin (respectively, is a bounded set) exactly when it contains (respectively, it is contained in) a non-zero scalar multiple of this ball; so this is one instance where the topological and bornological notions are distinct but complementary (in the sense that their definitions differ only by which of

\subseteq

and

\supseteq

is used).Other times, the distinction between topological and bornological notions may even be unnecessary. For example, for linear maps between normed spaces, being continuous (a topological notion) is equivalent to being bounded (a bornological notion). Although the distinction between topology and bornology is often blurred or unnecessary for normed space, it becomes more important when studying generalizations of normed spaces. Nevertheless, bornology and topology can still be thought of as two necessary, distinct, and complementary aspects of one and the same reality.

The general theory of topological vector spaces arose first from the theory of normed spaces and then bornology emerged from this general theory of topological vector spaces, although bornology has since become recognized as a fundamental notion in functional analysis. Born from the work of George Mackey (after whom Mackey spaces are named), the importance of bounded subsets first became apparent in duality theory, especially because of the Mackey–Arens theorem and the Mackey topology. Starting around the 1950s, it became apparent that topological vector spaces were inadequate for the study of certain major problems. For example, the multiplication operation of some important topological algebras was not continuous, although it was often bounded. Other major problems for which TVSs were found to be inadequate was in developing a more general theory of differential calculus, generalizing distributions from (the usual) scalar-valued distributions to vector or operator-valued distributions, and extending the holomorphic functional calculus of Gelfand (which is primarily concerted with Banach algebras or locally convex algebras) to a broader class of operators, including those whose spectra are not compact. Bornology has been found to be a useful tool for investigating these problems and others, including problems in algebraic geometry and general topology.

Definitions

A on a set is a cover of the set that is closed under finite unions and taking subsets. Elements of a bornology are called .

Explicitly, a or on a set

is a family

l{B} ≠ \varnothing

of subsets of

such that

l{B}

is stable under inclusion or : If
B\inl{B}

then every subset of
B

is an element of
l{B}.
- Stated in plain English, this says that subsets of bounded sets are bounded.
l{B}

covers
X:

Every point of
X

is an element of some
B\inl{B},

or equivalently,
X={stylecup\limits_B

} B}.
- Assuming (1), this condition may be replaced with: For every
x\inX,

\{x\}\inl{B}.

In plain English, this says that every point is bounded.
l{B}

is stable under finite unions: The union of finitely many elements of
l{B}

is an element of
l{B},

or equivalently, the union of any sets belonging to
l{B}

also belongs to
l{B}.
- In plain English, this says that the union of two bounded sets is a bounded set.

in which case the pair

(X,l{B})

is called a or a .

Thus a bornology can equivalently be defined as a downward closed cover that is closed under binary unions.A non-empty family of sets that closed under finite unions and taking subsets (properties (1) and (3)) is called an (because it is an ideal in the Boolean algebra/field of sets consisting of all subsets). A bornology on a set

can thus be equivalently defined as an ideal that covers

Elements of

l{B}

are called or simply, if

l{B}

is understood. Properties (1) and (2) imply that every singleton subset of

is an element of every bornology on

property (3), in turn, guarantees that the same is true of every finite subset of

In other words, points and finite subsets are always bounded in every bornology. In particular, the empty set is always bounded.

(X,l{B})

is a bounded structure and

X\notinl{B},

then the set of complements

\{X\setminusB:B\inl{B}\}

is a (proper) filter called the ; it is always a, which by definition means that it has empty intersection/kernel, because

\{x\}\inl{B}

for every

x\inX.

Bases and subbases

l{A}

and

l{B}

are bornologies on

then

l{B}

is said to be or than

l{A}

and also

l{A}

is said to be or than

l{B}

l{A}\subseteql{B}.

l{A}

is called a or of a bornology

l{B}

l{A}\subseteql{B}

and for every

B\inl{B},

there exists an

A\inl{A}

such that

B\subseteqA.

A family of sets

l{S}

is called a of a bornology

l{B}

l{S}\subseteql{B}

and the collection of all finite unions of sets in

l{S}

forms a base for

l{B}.

Every base for a bornology is also a subbase for it.

Generated bornology

The intersection of any collection of (one or more) bornologies on

is once again a bornology on

Such an intersection of bornologies will cover

because every bornology on

contains every finite subset of

(that is, if

l{B}

is a bornology on

and

F\subseteqX

is finite then

F\inl{B}

). It is readily verified that such an intersection will also be closed under (subset) inclusion and finite unions and thus will be a bornology on

Given a collection

l{S}

of subsets of

the smallest bornology on

containing

l{S}

is called the . It is equal to the intersection of all bornologies on

that contain

l{S}

as a subset. This intersection is well-defined because the power set

\wp(X)

is always a bornology on

so every family

l{S}

of subsets of

is always contained in at least one bornology on

Bounded maps

Suppose that

(X,l{A})

and

(Y,l{B})

are bounded structures. A map

f:X\toY

is called a, or just a, if the image under

of every

l{A}

-bounded set is a

l{B}

-bounded set; that is, if for every

A\inl{A},

f(A)\inl{B}.

Since the composition of two locally bounded map is again locally bounded, it is clear that the class of all bounded structures forms a category whose morphisms are bounded maps. An isomorphism in this category is called a and it is a bijective locally bounded map whose inverse is also locally bounded.

Examples of bounded maps

f:X\toY

is a continuous linear operator between two topological vector spaces (not necessarily Hausdorff), then it is a bounded linear operator when

and

have their von-Neumann bornologies, where a set is bounded precisely when it is absorbed by all neighbourhoods of origin (these are the subsets of a TVS that are normally called bounded when no other bornology is explicitly mentioned.). The converse is in general false.

A sequentially continuous map

f:X\toY

between two TVSs is necessarily locally bounded.

General constructions

Discrete bornology

For any set

the power set

\wp(X)

is a bornology on

called the . Since every bornology on

is a subset of

\wp(X),

the discrete bornology is the finest bornology on

(X,l{B})

is a bounded structure then (because bornologies are downward closed)

l{B}

is the discrete bornology if and only if

X\inl{B}.

Indiscrete bornology

For any set

the set of all finite subsets of

is a bornology on

called the . It is the coarsest bornology on

meaning that it is a subset of every bornology on

Sets of bounded cardinality

The set of all countable subsets of

is a bornology on

More generally, for any infinite cardinal

\kappa,

the set of all subsets of

having cardinality at most

\kappa

is a bornology on

Inverse image bornology

f:S\toX

is a map and

l{B}

is a bornology on

then

\left[f^-1(l{B})\right]

denotes the bornology generated by

f^-1(l{B}):=\left\{f^-1(B):B\inl{B}\right\},

which is called it the or the induced by

Let

be a set,

\left(T_i,l{B}_i\right)_i

be an

-indexed family of bounded structures, and let

\left(f_i\right)_i

be an

-indexed family of maps where

f_i:S\toT_i

for every

i\inI.

The

l{A}

determined by these maps is the strongest bornology on

making each

f_i:(S,l{A})\to\left(T_i,l{B}_i\right)

locally bounded. This bornology is equal to

{stylecap\limits_i\left[f^-1\left(l{B}_{i\right)\right]}.}

Direct image bornology

Let

be a set,

\left(T_i,l{B}_i\right)_i

be an

-indexed family of bounded structures, and let

\left(f_i\right)_i

be an

-indexed family of maps where

f_i:T_i\toS

for every

i\inI.

The

l{A}

determined by these maps is the weakest bornology on

making each

f_i:\left(T_i,l{B}_i\right)\to(S,l{A})

locally bounded. If for each

i\inI,

l{A}_i

denotes the bornology generated by

f\left(l{B}_i\right),

then this bornology is equal to the collection of all subsets

of the form

\cup_iA_i

where each

A_i\inl{A}_i

and all but finitely many

A_i

are empty.

Subspace bornology

Suppose that

(X,l{B})

is a bounded structure and

be a subset of

The

l{A}

is the finest bornology on

making the inclusion map

(S,l{A})\to(X,l{B})

into

(defined by

s\mapstos

) locally bounded.

Product bornology

Let

\left(X_i,l{B}_i\right)_i

be an

-indexed family of bounded structures, let

X={style\prod\limits_iX_i},

and for each

i\inI,

let

f_i:X\toX_i

denote the canonical projection. The on

is the inverse image bornology determined by the canonical projections

f_i:X\toX_i.

That is, it is the strongest bornology on

making each of the canonical projections locally bounded. A base for the product bornology is given by

{style\left\{\prod\limits_iB_i~:~B_i\inl{B}_iforalli\inI\right\}}.

Topological constructions

Compact bornology

is called relatively compact if its closure is a compact subspace of

For any topological space

in which singleton subsets are relatively compact (such as a T1 space), the set of all relatively compact subsets of

form a bornology on

called the on

Every continuous map between T1 spaces is bounded with respect to their compact bornologies.

The set of relatively compact subsets of

form a bornology on

\R.

A base for this bornology is given by all closed intervals of the form

[-n,n]

for

n=1,2,3,\ldots.

Metric bornology

(X,d),

the consists of all subsets

S\subseteqX

such that the supremum

\sup_s,d(s,t)<infty

is finite.

(X,\Omega,\mu),

the family of all measurable subsets

S\in\Omega

of finite measure (meaning

\mu(S)<infty

) form a bornology on

Closure and interior bornologies

Suppose that

is a topological space and

l{B}

is a bornology on

The bornology generated by the set of all topological interiors of sets in

l{B}

(that is, generated by

\{\operatorname{int}B:B\inl{B}\}

is called the of

l{B}

and is denoted by

\operatorname{int}l{B}.

The bornology

l{B}

is called if

l{B}=\operatorname{int}l{B}.

The bornology generated by the set of all topological closures of sets in

l{B}

(that is, generated by

\{\operatorname{cl}B:B\inl{B}\}

) is called the of

l{B}

and is denoted by

\operatorname{cl}l{B}.

We necessarily have

\operatorname{int}l{B}\subseteql{B}\subseteq\operatorname{cl}l{B}.

The bornology

l{B}

is called if it satisfies any of the following equivalent conditions:

l{B}=\operatorname{cl}l{B};
the closed subsets of
X

generate
l{B}

;
the closure of every
B\inl{B}

belongs to
l{B}.

The bornology

l{B}

is called if

l{B}

is both open and closed.

The topological space

is called or just if every

x\inX

has a neighborhood that belongs to

l{B}.

Every compact subset of a locally bounded topological space is bounded.

Bornology of a topological vector space

Topological rings

Suppose that

is a commutative topological ring. A subset

is called a if for each neighborhood

of the origin in

there exists a neighborhood

of the origin in

such that

SV\subseteqU.

References

- Hogbe-Nlend. Henri. Henri Hogbe-Nlend. Les racines historiques de la bornologie moderne. Séminaire Choquet: Initiation à l'analyse. French. 10. 1. 1971. 1–7. 477660.

Notes and References

Block. Jonathan. Daenzer. Calder. 2009-01-09. Mukai duality for gerbes with connection. math.QA. 0803.1529.