Homeomorphism: Difference between revisions
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In [[mathematics]], a '''homeomorphism''' is a [[function]] that maps one [[topological space]] to another with the property that it is [[bijective function|bijective]] and both the function and its [[inverse function|inverse]] are [[continuity#Continuous function|continuous]] with respect to the associated topologies. A homeomorphism indicates that the two topological spaces are "geometrically" alike, in the sense that points that are "close" in one space are mapped to points which are also "close" in the other, while points that are "distant" are also mapped to points which are also "distant". In [[ | {{subpages}} | ||
In [[mathematics]], a '''homeomorphism''' is a [[function]] that maps one [[topological space]] to another with the property that it is [[bijective function|bijective]] and both the function and its [[inverse function|inverse]] are [[continuity#Continuous function|continuous]] with respect to the associated topologies. A homeomorphism indicates that the two topological spaces are "geometrically" alike, in the sense that points that are "close" in one space are mapped to points which are also "close" in the other, while points that are "distant" are also mapped to points which are also "distant". In [[differential geometry]], this means that one topological space can be deformed into the other by "bending" and "stretching". | |||
==Formal definition== | ==Formal definition== | ||
Let <math>( | Let <math>\scriptstyle (X,O_X)</math> and <math>\scriptstyle (Y,O_Y)</math> be topological spaces. A function <math>\scriptstyle f:(X,O_X)\rightarrow (Y,O_Y)</math> is a homeomorphism between <math>\scriptstyle (X,O_X)</math> and <math>\scriptstyle (Y,O_Y)</math> if it has the following properties: | ||
#f is a bijective function (i.e., it is [[injective function|one-to-one]] and [[surjective function|onto]]) | #f is a bijective function (i.e., it is [[injective function|one-to-one]] and [[surjective function|onto]]) | ||
#f is continuous | #f is continuous | ||
#The inverse function <math>f^{-1}:(Y,O_Y) \rightarrow (X,O_X)</math> is a continuous function. | #The inverse function <math>\scriptstyle f^{-1}:(Y,O_Y) \rightarrow (X,O_X)</math> is a continuous function. | ||
If some homeomorphism exists between two topological spaces <math>( | If some homeomorphism exists between two topological spaces <math>\scriptstyle (X,O_X)</math> and <math>\scriptstyle (Y,O_Y)</math> then they are said to be '''homeomorphic''' to one another. Homeomorphism (in the sense of being homeomorphic) is an [[equivalence relation]]. | ||
==Topological property== | |||
A '''topological property''' is one which is preserved by homeomorphism. Examples include | |||
* [[Compact space|Compactness]]; | |||
* [[Connected space|Connectedness]].[[Category:Suggestion Bot Tag]] |
Latest revision as of 16:01, 28 August 2024
In mathematics, a homeomorphism is a function that maps one topological space to another with the property that it is bijective and both the function and its inverse are continuous with respect to the associated topologies. A homeomorphism indicates that the two topological spaces are "geometrically" alike, in the sense that points that are "close" in one space are mapped to points which are also "close" in the other, while points that are "distant" are also mapped to points which are also "distant". In differential geometry, this means that one topological space can be deformed into the other by "bending" and "stretching".
Formal definition
Let and be topological spaces. A function is a homeomorphism between and if it has the following properties:
- f is a bijective function (i.e., it is one-to-one and onto)
- f is continuous
- The inverse function is a continuous function.
If some homeomorphism exists between two topological spaces and then they are said to be homeomorphic to one another. Homeomorphism (in the sense of being homeomorphic) is an equivalence relation.
Topological property
A topological property is one which is preserved by homeomorphism. Examples include