Cauchy space explained

In general topology and analysis, a Cauchy space is a generalization of metric spaces and uniform spaces for which the notion of Cauchy convergence still makes sense. Cauchy spaces were introduced by H. H. Keller in 1968, as an axiomatic tool derived from the idea of a Cauchy filter, in order to study completeness in topological spaces. The category of Cauchy spaces and Cauchy continuous maps is Cartesian closed, and contains the category of proximity spaces.

Definition

Throughout,

is a set,

\wp(X)

denotes the power set of

and all filters are assumed to be proper/non-degenerate (i.e. a filter may not contain the empty set).

A Cauchy space is a pair

(X,C)

consisting of a set

together a family

C\subseteq\wp(\wp(X))

of (proper) filters on

having all of the following properties:

For each

x\inX,

the discrete ultrafilter at

denoted by

U(x),

is in

F\inC,

is a proper filter, and

is a subset of

then

G\inC.

F,G\inC

and if each member of

intersects each member of

then

F\capG\inC.

An element of

is called a Cauchy filter, and a map

between Cauchy spaces

(X,C)

and

(Y,D)

is Cauchy continuous if

\uparrowf(C)\subseteqD

; that is, the image of each Cauchy filter in

is a Cauchy filter base in

Properties and definitions

Any Cauchy space is also a convergence space, where a filter

converges to

F\capU(x)

is Cauchy. In particular, a Cauchy space carries a natural topology.

Examples

Any uniform space (hence any metric space, topological vector space, or topological group) is a Cauchy space; see Cauchy filter for definitions.
A lattice-ordered group carries a natural Cauchy structure.

may be made into a Cauchy space by declaring a filter

to be Cauchy if, given any element

n\inA,

there is an element

U\inF

such that

is either a singleton or a subset of the tail

\{m:m\geqn\}.

Then given any other Cauchy space

the Cauchy-continuous functions from

are the same as the Cauchy nets in

indexed by

is complete, then such a function may be extended to the completion of

which may be written

A\cup\{infty\};

the value of the extension at

infty

will be the limit of the net. In the case where

is the set

\{1,2,3,\ldots\}

of natural numbers (so that a Cauchy net indexed by

is the same as a Cauchy sequence), then

receives the same Cauchy structure as the metric space

\{1,1/2,1/3,\ldots\}.

Category of Cauchy spaces

The natural notion of morphism between Cauchy spaces is that of a Cauchy-continuous function, a concept that had earlier been studied for uniform spaces.

References

Eva Lowen-Colebunders (1989). Function Classes of Cauchy Continuous Maps. Dekker, New York, 1989.