Difference between revisions of "871 - Topology"

From Queer Beagle Wiki
 
(11 intermediate revisions by the same user not shown)
Line 4: Line 4:
  
 
===Metrizability===
 
===Metrizability===
 +
:''see also'' [[Metrizability]]
 +
 +
A topological space <math> (X,\mathcal{T}_X) </math> is metrizable if there is a metric <math>d </math> on <math> X</math> such that <math>\mathcal{T}_X = \mathcal{T}_d </math>, where <math> \mathcal{T}_d </math> is the metric topology on <math> X</math> induced by <math> d</math>.
 +
 +
Metrizability is a homeomorphism invariant. Metrizability is not preserved by quotients, continuous images, or continuous preimages. Metrizable spaces are <math> \mathcal{T}_4 </math>.
  
 
===Connectedness===
 
===Connectedness===
Line 10: Line 15:
  
 
===Compactness===
 
===Compactness===
 +
:''see also:'' [[Compact]]
  
 
===Separation Properties ===
 
===Separation Properties ===
Line 17: Line 23:
  
 
====<math>T_2 </math> (Hausdorff) ====
 
====<math>T_2 </math> (Hausdorff) ====
 +
:''See also'' [[ T2 (Hausdorff)]]
  
 
====<math>T_3 </math> (Regular) ====
 
====<math>T_3 </math> (Regular) ====
A topological space <math>X </math> is <math>T_3 </math> if it is <math>T_1 </math> and for any point <math> a \in X</math> and closed set <math>B \in X </math> with <math>a \not \in B </math>, there are disjoint open sets <math>U,V \in X </math> with <math>a\in U </math> and <math>B\sube V  </math>
+
A topological space <math>X </math> is <math>T_3 </math> if it is <math>T_1 </math> and for any point <math> a \in X</math> and closed set <math>B \in X </math> with <math>a \not \in B </math>, there are disjoint open sets <math>U,V \in X </math> with <math>a\in U </math> and <math>B\subseteq V  </math>
  
 
====<math>T_4 </math> (Normal)====
 
====<math>T_4 </math> (Normal)====
A topological space <math>X </math> is <math>T_4 </math> if it is <math>T_1 </math>and for any two disjoint closed sets <math>A,B \in X </math> there are disjoint open sets <math>U,V \in X </math> with <math> A \sube U</math> and <math>B \sube V </math>.
+
A topological space <math>X </math> is <math>T_4 </math> if it is <math>T_1 </math>and for any two disjoint closed sets <math>A,B \in X </math> there are disjoint open sets <math>U,V \in X </math> with <math> A \subseteq U</math> and <math>B \subseteq V </math>.
 +
 
 +
==Homotopy==
 +
 
 +
==Fundamental Groups==

Latest revision as of 22:02, 21 May 2023


Homeomorphism Invariants

Metrizability

see also Metrizability

A topological space \( (X,\mathcal{T}_X) \) is metrizable if there is a metric \(d \) on \( X\) such that \(\mathcal{T}_X = \mathcal{T}_d \), where \( \mathcal{T}_d \) is the metric topology on \( X\) induced by \( d\).

Metrizability is a homeomorphism invariant. Metrizability is not preserved by quotients, continuous images, or continuous preimages. Metrizable spaces are \( \mathcal{T}_4 \).

Connectedness

Path Connected

Compactness

see also: Compact

Separation Properties

\(T_1 \)

A topological space \(X \) is \(T_1 \) if for any two distinct points \( a,b\in X\) there are open sets \( U,V\) in \(X \) with \(a\in U, b\not \in U, a\not\in V, b\in V \).

\(T_2 \) (Hausdorff)

See also T2 (Hausdorff)

\(T_3 \) (Regular)

A topological space \(X \) is \(T_3 \) if it is \(T_1 \) and for any point \( a \in X\) and closed set \(B \in X \) with \(a \not \in B \), there are disjoint open sets \(U,V \in X \) with \(a\in U \) and \(B\subseteq V \)

\(T_4 \) (Normal)

A topological space \(X \) is \(T_4 \) if it is \(T_1 \)and for any two disjoint closed sets \(A,B \in X \) there are disjoint open sets \(U,V \in X \) with \( A \subseteq U\) and \(B \subseteq V \).

Homotopy

Fundamental Groups