Homeomorphism

Not to be confused with Homomorphism

Homeomorphism of metric spaces

Given two metric spaces [ilmath](X,d)[/ilmath] and [ilmath](Y,d')[/ilmath] they are said to be homeomorphic^[1] if:

• There exists a mapping [ilmath]f:(X,d)\rightarrow(Y,d')[/ilmath] such that:
  1. [ilmath]f[/ilmath] is bijective
  2. [ilmath]f[/ilmath] is continuous
  3. [ilmath]f^{-1} [/ilmath] is also a continuous map

Then [ilmath](X,d)[/ilmath] and [ilmath](Y,d')[/ilmath] are homeomorphic and we may write [ilmath](X,d)\cong(Y,d')[/ilmath] or simply (as Mathematicians are lazy) [ilmath]X\cong Y[/ilmath] if the metrics are obvious

TODO: Find reference for use of [ilmath]\cong[/ilmath] notation

Topological Homeomorphism

A topological homeomorphism is bijective map between two topological spaces [math]f:(X,\mathcal{J})\rightarrow(Y,\mathcal{K})[/math] where:

1. [math]f[/math] is bijective
2. [math]f[/math] is continuous
3. [math]f^{-1}[/math] is continuous

Technicalities

This section contains pedantry. The reader should be aware of it, but not concerned by not considering it In order for [ilmath]f^{-1} [/ilmath] to exist, [ilmath]f[/ilmath] must be bijective. So the definition need only require^[2]:

1. [ilmath]f[/ilmath] be continuous
2. [ilmath]f^{-1} [/ilmath] exists and is continuous.

Agreement with metric definition

Using Continuity definitions are equivalent it is easily seen that the metric space definition implies the topological definition. That is to say:

• If [ilmath]f[/ilmath] is a (metric) homeomorphism then is is also a topological one (when the topologies considered are those those induced by the metric.

See also

• Composition of continuous maps is continuous

References

1. ↑ Functional Analysis - George Bachman Lawrence Narici
2. ↑ Fundamentals of Algebraic Topology, Steven H. Weintraub