Regular space: Difference between revisions

Latest revision as of 16:37, 28 January 2012

There are two alternative definitions of the term. Please see: Convention:Hausdorffness assumption

Definition

A topological space is said to be regular if it satisfies the following equivalent conditions:

No.	Shorthand	A topological space is said to be regular if ...	A topological space $X$ is said to be regular if ...
1	separation of point and closed subset not containing it	given any point and a closed subset not containing it, there are disjoint open subsets containing them.	given any point $x\in X$ and closed subset $A\subseteq X$ such that $x\notin A$ , there exist disjoint open subsets $U,V$ of $X$ such that $x\in U,A\subseteq V$ , and $U\cap V=\varnothing$ .
2	open neighborhood contains closure of smaller open neighborhood	given any point and an open subset containing it, there is an open subset containing the point whose closure lies in the original open subset.	given any point $x\in X$ and open subset $V\subseteq X$ such that $x\in V$ , there exists an open subset $U\subseteq X$ such that $x\in U$ and the closure ${\overline {U}}$ is contained in $V$ .
3	separation of compact subset and closed subset	given a compact subset and a closed subset that are disjoint, there are disjoint open subsets containing them.	given any two subsets $A,B\subseteq X$ such that $A\cap B=\varnothing$ , $A$ is compact and $B$ is closed, there exist disjoint open subsets $U,V$ of $X$ such that $A\subseteq U,B\subseteq V$ , and $U\cap V=\varnothing$ .
4	basis element contains closure of smaller basis element	(fix a choice of basis of open subsets) given any point and a basis open subset containing it, there is a basis open subset containing the point whose closure lies in the original open subset.	given any point $x\in X$ and a basis open subset $V\subseteq X$ such that $x\in V$ , there exists a basis open subset $U\subseteq X$ such that $x\in U$ and the closure ${\overline {U}}$ is contained in $V$ .
5	basis element contains closure of smaller open subset	(fix a choice of basis of open subsets) given any point and a basis open subset containing it, there is an open subset containing the point whose closure lies in the original open subset.	given any point $x\in X$ and a basis open subset $V\subseteq X$ such that $x\in V$ , there exists an open subset $U\subseteq X$ such that $x\in U$ and the closure ${\overline {U}}$ is contained in $V$ .
6	open subset contains basis element	(fix a choice of basis of open subsets) given any point and an open subset containing it, there is a basis open subset containing the point whose closure lies in the original open subset.	given any point $x\in X$ and an open subset $V\subseteq X$ such that $x\in V$ , there exists a basis open subset $U\subseteq X$ such that $x\in U$ and the closure ${\overline {U}}$ is contained in $V$ .

Outside of point-set topology, the term regular space is often used for a regular Hausdorff space, which is the same thing as a regular T1 space. This convention is, however, eschewed by point-set topologists.

This article defines a property of topological space that is pivotal (viz important) among currently studied properties of topological spaces

This article is about a basic definition in topology.
VIEW: Definitions built on this | Facts about this | Survey articles about this
View a complete list of basic definitions in topology

Relation with other properties

Conjunction with other properties

Regular Lindelof space: Conjunction with the property of being a Lindelof space.

Stronger properties

Property	Meaning	Intermediate notions
metrizable space	underlying topological space of a metric space	Completely regular space, Monotonically normal space, Moore space, Normal Hausdorff space, Regular Hausdorff space, Tychonoff space\|FULL LIST, MORE INFO
CW-space	topological space arising as the underlying space of a CW-complex	Completely regular space, Normal Hausdorff space, Regular Hausdorff space\|FULL LIST, MORE INFO
completely regular space	point and closed subset not containing it can be separated by continuous function	\|FULL LIST, MORE INFO
compact Hausdorff space	compact and Hausdorff	Normal Hausdorff space, Regular Hausdorff space, Tychonoff space\|FULL LIST, MORE INFO
locally compact Hausdorff space	locally compact and Hausdorff	Completely regular space, Regular Hausdorff space\|FULL LIST, MORE INFO
paracompact Hausdorff space		Normal Hausdorff space, Regular Hausdorff space\|FULL LIST, MORE INFO

Weaker properties

Property	Meaning	Proof of implication	Proof of strictness (reverse implication failure)	Intermediate notions
semiregular space		regular implies semiregular
locally regular space
preregular space		regular implies preregular
symmetric space

Metaproperties

Metaproperty name	Satisfied?	Proof	Statement with symbols
subspace-hereditary property of topological spaces	Yes	regularity is hereditary	If $X$ is a regular space and $A$ is a subset of $X$ , then $A$ is also a regular space under the subspace topology.
product-closed property of topological spaces	Yes	regularity is product-closed	If $X_{i},i\in I$ is a collection of regular spaces, then the product space $\prod _{i\in I}X_{i}$ is also regular with the product topology.
box product-closed property of topological spaces	Yes	regularity is box product-closed	If $X_{i},i\in I$ is a collection of regular spaces, then the product space $\prod _{i\in I}X_{i}$ is also regular with the box topology.
refining-preserved property of topological spaces	No	regularity is not refining-preserved	It is possible to have a topological space that is regular but such that passing to a finer topology gives a topological space that is not regular.

References

Textbook references

Topology (2nd edition) by James R. Munkres^{More info}, Page 195, Chapter 4, Section 31 (formal definition, along with normal space)
Lecture Notes on Elementary Topology and Geometry (Undergraduate Texts in Mathematics) by I. M. Singer and J. A. Thorpe^{More info}, Page 28 (formal definition)

@@ Line 1: / Line 1: @@
-{{topospace property}}
+''There are two alternative definitions of the term. Please see:'' [[Convention:Hausdorffness assumption]]
-{{T family|T3}}
+==Definition==
-{{basicdef}}
+A [[topological space]] is said to be '''regular''' if it satisfies the following equivalent conditions:
-==Definition==
+{| class="sortable" border="1"
+! No. !! Shorthand !! A topological space is said to be regular if ... !! A topological space <math>X</math> is said to be regular if ...
+|-
+| 1 || separation of point and closed subset not containing it || given any point and a [[closed subset]] not containing it, there are disjoint open subsets containing them. || given any point <math>x \in X</math> and closed subset <math>A \subseteq X</math> such that <math>x \notin A</math>, there exist disjoint open subsets <math>U,V</math> of <math>X</math> such that <math>x \in U, A \subseteq V</math>, and <math>U \cap V = \varnothing</math>.
+|-
+| 2 || open neighborhood contains closure of smaller open neighborhood || given any point and an [[open subset]] containing it, there is an open subset containing the point whose closure lies in the original open subset. || given any point <math>x \in X</math> and open subset <math>V \subseteq X</math> such that <math>x \in V</math>, there exists an open subset <math>U \subseteq X</math> such that <math>x \in U</math> and the [[closure]] <math>\overline{U}</math> is contained in <math>V</math>.
+|-
+| 3 || separation of compact subset and closed subset || given a compact subset and a closed subset that are disjoint, there are disjoint open subsets containing them. || given any two subsets <math>A,B \subseteq X</math> such that <math>A \cap B = \varnothing</math>, <math>A</math> is compact and <math>B</math> is closed, there exist disjoint open subsets <math>U,V</math> of <math>X</math> such that <math>A \subseteq U, B \subseteq V</math>, and <math>U \cap V = \varnothing</math>.
+|-
+| 4 || basis element contains closure of smaller basis element || (fix a choice of [[basis]] of [[open subset]]s) given any point and a basis [[open subset]] containing it, there is a basis open subset containing the point whose closure lies in the original open subset. || given any point <math>x \in X</math> and a basis open subset <math>V \subseteq X</math> such that <math>x \in V</math>, there exists a basis open subset <math>U \subseteq X</math> such that <math>x \in U</math> and the [[closure]] <math>\overline{U}</math> is contained in <math>V</math>.
+|-
+| 5 || basis element contains closure of smaller open subset || (fix a choice of [[basis]] of [[open subset]]s) given any point and a basis [[open subset]] containing it, there is an open subset containing the point whose closure lies in the original open subset. || given any point <math>x \in X</math> and a basis open subset <math>V \subseteq X</math> such that <math>x \in V</math>, there exists an open subset <math>U \subseteq X</math> such that <math>x \in U</math> and the [[closure]] <math>\overline{U}</math> is contained in <math>V</math>.
+|-
+| 6 || open subset contains basis element || (fix a choice of [[basis]] of [[open subset]]s) given any point and an [[open subset]] containing it, there is a basis open subset containing the point whose closure lies in the original open subset. || given any point <math>x \in X</math> and an open subset <math>V \subseteq X</math> such that <math>x \in V</math>, there exists a basis open subset <math>U \subseteq X</math> such that <math>x \in U</math> and the [[closure]] <math>\overline{U}</math> is contained in <math>V</math>.
+|}
-===Symbol-free definition===
+Outside of point-set topology, the term ''regular space'' is often used for a [[regular Hausdorff space]], which is the same thing as a regular [[T1 space]]. This convention is, however, eschewed by point-set topologists.
-A [[topological space]] is said to be '''reguilar''' if it satisfies the following two conditions:
+{{pivotal topospace property}}
-* It is a [[T1 space]] viz all points are closed
+{{basicdef}}
-* Given a point and a closed set not containing it, there are disjoint open sets containing the point and the closed set respectively.
 ==Relation with other properties==
+===Conjunction with other properties===
+* [[Regular Lindelof space]]: Conjunction with the property of being a [[Lindelof space]].
 ===Stronger properties===
-* [[Normal space]]
+{| class="sortable" border="1"
-* [[Completely regular space]]
+! Property !! Meaning !! Proof of implication !! Proof of strictness (reverse implication failure) !! Intermediate notions
+|-
+| [[Weaker than::metrizable space]] || underlying topological space of a [[metric space]] ||  || || {{intermediate notions short|regular space|metrizable space}}
+|-
+| [[Weaker than::CW-space]] || topological space arising as the underlying space of a [[CW-complex]] || || || {{intermediate notions short|regular space|CW-space}}
+|-
+| [[Weaker than::completely regular space]] || point and closed subset not containing it can be separated by continuous function || || || {{intermediate notions short|regular space|completely regular space}}
+|-
+| [[Weaker than::compact Hausdorff space]] || [[compact space|compact]] and [[Hausdorff space|Hausdorff]] || || || {{intermediate notions short|regular space|compact Hausdorff space}}
+|-
+| [[Weaker than::locally compact Hausdorff space]] || [[locally compact space|locally compact]] and [[Hausdorff space|Hausdorff]] || || || {{intermediate notions short|regular space|locally compact Hausdorff space}}
+|-
+| [[Weaker than::paracompact Hausdorff space]] || || || || {{intermediate notions short|regular space|paracompact Hausdorff space}}
+|}
 ===Weaker properties===
-* [[Hausdorff space]]
+{| class="sortable" border="1"
-* [[T1 space]]
+! Property !! Meaning !! Proof of implication !! Proof of strictness (reverse implication failure) !! Intermediate notions
-* [[T0 space]]
+|-
+| [[Stronger than::semiregular space]] || || [[regular implies semiregular]] || ||
+|-
+| [[Stronger than::locally regular space]] || || || ||
+|-
+| [[Stronger than::preregular space]] || || [[regular implies preregular]] || ||
+|-
+| [[Stronger than::symmetric space]] || || || ||
+|}
+==Metaproperties==
+{| class="sortable" border="1"
+!Metaproperty name !! Satisfied? !! Proof !! Statement with symbols
+|-
+| [[satisfies metaproperty::subspace-hereditary property of topological spaces]] || Yes || [[regularity is hereditary]] || If <math>X</math> is a [[regular space]] and <math>A</math> is a subset of <math>X</math>, then <matH>A</math> is also a regular space under the [[subspace topology]].
+|-
+| [[satisfies metaproperty::product-closed property of topological spaces]] || Yes || [[regularity is product-closed]] || If <math>X_i, i \in I</math> is a collection of regular spaces, then the product space <math>\prod_{i \in I} X_i</math> is also regular with the [[product topology]].
+|-
+| [[satisfies metaproperty::box product-closed property of topological spaces]]|| Yes || [[regularity is box product-closed]] || If <math>X_i, i \in I</math> is a collection of regular spaces, then the product space <math>\prod_{i \in I} X_i</math> is also regular with the [[box topology]].
+|-
+| [[dissatisfies metaproperty::refining-preserved property of topological spaces]] || No || [[regularity is not refining-preserved]] || It is possible to have a topological space that is regular but such that passing to a [[finer topology]] gives a topological space that is not regular.
+|}
+==References==
+===Textbook references===
+* {{booklink-defined|Munkres}}, Page 195, Chapter 4, Section 31 (formal definition, along with [[normal space]])
+* {{booklink-defined|SingerThorpe}}, Page 28 (formal definition)