In topology, a proximity space, also called a nearness space, is an axiomatization of the intuitive notion of "nearness" that hold set-to-set, as opposed to the better known point-to-set notion that characterize topological spaces.
The concept was described by but ignored at the time.[1] It was rediscovered and axiomatized by V. A. Efremovič in 1934 under the name of infinitesimal space, but not published until 1951. In the interim, discovered a version of the same concept under the name of separation space.
A
(X,\delta)
X
\delta
X
For all subsets
A,B,C\subseteqX
A \delta B
B \delta A
A \delta B
A ≠ \varnothing
A\capB ≠ \varnothing
A \delta B
A \delta (B\cupC)
A \delta B
A \delta C
E,
A \delta E
B \delta (X\setminusE)
A \delta B
If
A \delta B
A
B
A
B
A
B
B
A,
A\llB,
A
X\setminusB
The main properties of this set neighborhood relation, listed below, provide an alternative axiomatic characterization of proximity spaces.
For all subsets
A,B,C,D\subseteqX
X\llX
A\llB
A\subseteqB
A\subseteqB\llC\subseteqD
A\llD
A\llB
A\llC
A\llB\capC
A\llB
X\setminusB\llX\setminusA
A\llB
E
A\llE\llB.
A proximity space is called if
\{x\} \delta \{y\}
x=y.
A or is one that preserves nearness, that is, given
f:(X,\delta)\to\left(X*,\delta*\right),
A \delta B
X,
f[A] \delta* f[B]
X*.
C\ll*D
X*,
f-1[C]\llf-1[D]
X.
Given a proximity space, one can define a topology by letting
A\mapsto\left\{x:\{x\} \delta A\right\}
The resulting topology is always completely regular. This can be proven by imitating the usual proofs of Urysohn's lemma, using the last property of proximal neighborhoods to create the infinite increasing chain used in proving the lemma.
Given a compact Hausdorff space, there is a unique proximity space whose corresponding topology is the given topology:
A
B
X
A
B
A x B