Quotient map: Difference between revisions
No edit summary |
m (2 revisions) |
||
| (One intermediate revision by the same user not shown) | |||
| Line 14: | Line 14: | ||
Given a topological space <math>X</math>, a ''set'' <math>Y</math> and a surjective map <math>f:X \to Y</math>, we can prescribe a unique topology on <math>Y</math>, the so-called [[quotient topology]], such that <math>f</math> is a quotient map. Moreover, this is the [[coarser topology|coarsest]] topology for which <math>f</math> becomes continuous. | Given a topological space <math>X</math>, a ''set'' <math>Y</math> and a surjective map <math>f:X \to Y</math>, we can prescribe a unique topology on <math>Y</math>, the so-called [[quotient topology]], such that <math>f</math> is a quotient map. Moreover, this is the [[coarser topology|coarsest]] topology for which <math>f</math> becomes continuous. | ||
Also, the study of a quotient map is equivalent to the study of the equivalence relation on <math>X</math> given by <math>x \simeq y \iff f(x) = f(y)</math>. | |||
==Relation with other properties== | ==Relation with other properties== | ||
Latest revision as of 19:57, 11 May 2008
This article defines a property of continuous maps between topological spaces
Definition
Symbol-free definition
A continuous map between topological spaces is termed a quotient map if it is surjective, and if a set in the range space is open iff its inverse image is open in the domain space.
Definition with symbols
Let be topological spaces and be continuous maps. is termed a quotient map if it is sujective and if is open iff is open in .
Significance
Given a topological space , a set and a surjective map , we can prescribe a unique topology on , the so-called quotient topology, such that is a quotient map. Moreover, this is the coarsest topology for which becomes continuous.
Also, the study of a quotient map is equivalent to the study of the equivalence relation on given by .
