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 Frigyes Riesz (1909) 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, A. D. Wallace (1941) discovered a version of the same concept under the name of separation space.

Definition

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A proximity space   is a set   with a relation   between subsets of   satisfying the following properties:

For all subsets  

  1.   implies  
  2.   implies  
  3.   implies  
  4.   implies (  or  )
  5. (For all     or  ) implies  

Proximity without the first axiom is called quasi-proximity (but then Axioms 2 and 4 must be stated in a two-sided fashion).

If   we say   is near   or   and   are proximal; otherwise we say   and   are apart. We say   is a proximal- or  -neighborhood of   written   if and only if   and   are apart.

The main properties of this set neighborhood relation, listed below, provide an alternative axiomatic characterization of proximity spaces.

For all subsets  

  1.  
  2.   implies  
  3.   implies  
  4. (  and  ) implies  
  5.   implies  
  6.   implies that there exists some   such that  

A proximity space is called separated if  implies  

A proximity or proximal map is one that preserves nearness, that is, given   if   in   then   in   Equivalently, a map is proximal if the inverse map preserves proximal neighborhoodness. In the same notation, this means if   holds in   then   holds in  

Properties

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Given a proximity space, one can define a topology by letting   be a Kuratowski closure operator. If the proximity space is separated, the resulting topology is Hausdorff. Proximity maps will be continuous between the induced topologies.

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:   is near   if and only if their closures intersect. More generally, proximities classify the compactifications of a completely regular Hausdorff space.

A uniform space   induces a proximity relation by declaring   is near   if and only if   has nonempty intersection with every entourage. Uniformly continuous maps will then be proximally continuous.

See also

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References

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  1. ^ W. J. Thron, Frederic Riesz' contributions to the foundations of general topology, in C.E. Aull and R. Lowen (eds.), Handbook of the History of General Topology, Volume 1, 21-29, Kluwer 1997.
  • Efremovič, V. A. (1951), "Infinitesimal spaces", Doklady Akademii Nauk SSSR, New Series (in Russian), 76: 341–343, MR 0040748
  • Naimpally, Somashekhar A.; Warrack, Brian D. (1970). Proximity Spaces. Cambridge Tracts in Mathematics and Mathematical Physics. Vol. 59. Cambridge: Cambridge University Press. ISBN 0-521-07935-7. Zbl 0206.24601.
  • Riesz, F. (1909), "Stetigkeit und abstrakte Mengenlehre", Rom. 4. Math. Kongr. 2: 18–24, JFM 40.0098.07
  • Wallace, A. D. (1941), "Separation spaces", Ann. of Math., 2, 42 (3): 687–697, doi:10.2307/1969257, JSTOR 1969257, MR 0004756
  • Vita, Luminita; Bridges, Douglas (2001). "A Constructive Theory of Point-Set Nearness". CiteSeerX 10.1.1.15.1415.
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