Difference between revisions of "Passing to the quotient (topology)"

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: '''See ''[[passing to the quotient]]'' for other forms of this theorem'''
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==[[Passing to the quotient (topology)/Statement|Statement]]==
 
==[[Passing to the quotient (topology)/Statement|Statement]]==
 
{{:Passing to the quotient (topology)/Statement}}
 
{{:Passing to the quotient (topology)/Statement}}
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This is an instance of [[passing to the quotient (function)]] with functions between sets. In this proof we apply this theorem and show the result yields a continuous mapping (by assuming both {{M|f}} and {{M|\pi}} are continuous)
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==Proof==
 
==Proof==
 
==Notes==
 
==Notes==

Latest revision as of 17:43, 8 October 2016

See passing to the quotient for other forms of this theorem
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Statement

[ilmath]\xymatrix{ X \ar[d]_\pi \ar[dr]^f & \\ \frac{X}{\sim} \ar@{.>}[r]^{\overline{f} }& Y}[/ilmath]
[ilmath]f[/ilmath] descends to the quotient

Suppose that [ilmath](X,\mathcal{ J })[/ilmath] is a topological space and [ilmath]\sim[/ilmath] is an equivalence relation, let [ilmath](\frac{X}{\sim},\mathcal{ Q })[/ilmath] be the resulting quotient topology and [ilmath]\pi:X\rightarrow\frac{X}{\sim} [/ilmath] the resulting quotient map, then:

  • Let [ilmath](Y,\mathcal{ K })[/ilmath] be any topological space and let [ilmath]f:X\rightarrow Y[/ilmath] be a continuous map that is constant on the fibres of [ilmath]\pi[/ilmath][Note 1] then:
  • there exists a unique continuous map, [ilmath]\bar{f}:\frac{X}{\sim}\rightarrow Y[/ilmath] such that [ilmath]f=\overline{f}\circ\pi[/ilmath]

We may then say [ilmath]f[/ilmath] descends to the quotient or passes to the quotient

Note: this is an instance of passing-to-the-quotient for functions

This is an instance of passing to the quotient (function) with functions between sets. In this proof we apply this theorem and show the result yields a continuous mapping (by assuming both [ilmath]f[/ilmath] and [ilmath]\pi[/ilmath] are continuous)

Proof

Notes

  1. That means that:

References