Glossary of cue sports terms: Difference between revisions

Revision as of 07:53, 16 January 2014

In algebraic topology, an area of mathematics, a homeotopy group of a topological space is a homotopy group of the group of self-homeomorphisms of that space.

Definition

The homotopy group functors $\pi _{k}$ assign to each path-connected topological space $X$ the group $\pi _{k}(X)$ of homotopy classes of continuous maps $S^{k}\to X.$

Another construction on a space $X$ is the group of all self-homeomorphisms $X\to X$ , denoted ${\rm {Homeo}}(X).$ If X is a locally compact, locally connected Hausdorff space then a fundamental result of R. Arens says that ${\rm {Homeo}}(X)$ will in fact be a topological group under the compact-open topology.

Under the above assumptions, the homeotopy groups for $X$ are defined to be:

HME_{k}(X)=\pi _{k}({\rm {Homeo}}(X)).

Thus $HME_{0}(X)=\pi _{0}({\rm {Homeo}}(X))=MCG^{*}(X)$ is the extended mapping class group for $X.$ In other words, the extended mapping class group is the set of connected components of ${\rm {Homeo}}(X)$ as specified by the functor $\pi _{0}.$

Example

According to the Dehn-Nielsen theorem, if $X$ is a closed surface then $HME_{0}(X)={\rm {Out}}(\pi _{1}(X)),$ the outer automorphism group of its fundamental group.

References

G.S. McCarty. Homeotopy groups. Trans. A.M.S. 106(1963)293-304.
R. Arens, Topologies for homeomorphism groups, Amer. J. Math. 68 (1946), 593–610.

Template:Topology-stub

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+{{distinguish|homotopy}}
+In [[algebraic topology]], an area of [[mathematics]], a '''homeotopy group''' of a [[topological space]] is a [[homotopy group]] of the group of [[homeomorphism|self-homeomorphism]]s of that space.
+==Definition==
+The [[homotopy group]] [[functor]]s <math>\pi_k</math> assign to each [[path-connected]] topological space <math>X</math> the group <math>\pi_k(X)</math> of [[homotopy class]]es of continuous maps <math>S^k\to X.</math>
+Another construction on a space <math>X</math> is the [[Homeomorphism group|group of all self-homeomorphisms]] <math>X \to X</math>, denoted <math>{\rm Homeo}(X).</math> If ''X'' is a [[locally compact]], [[locally connected]] [[Hausdorff space]] then a fundamental result of [[R. Arens]] says that <math>{\rm Homeo}(X)</math> will in fact be a [[topological group]] under the [[compact-open topology]].
+Under the above assumptions, the '''homeotopy''' groups for <math>X</math> are defined to be:
+:<math>HME_k(X)=\pi_k({\rm Homeo}(X)).</math>
+Thus <math>HME_0(X)=\pi_0({\rm Homeo}(X))=MCG^*(X)</math> is the '''extended''' [[mapping class group]] for <math>X.</math> In other words, the extended mapping class group is the set of connected components of <math>{\rm Homeo}(X)</math> as specified by the functor <math>\pi_0.</math>
+==Example==
+According to the [[Dehn-Nielsen theorem]], if <math>X</math> is a closed surface then <math>HME_0(X)={\rm Out}(\pi_1(X)),</math> the [[outer automorphism group]] of its [[fundamental group]].
+==References==
+*G.S. McCarty. ''Homeotopy groups''. Trans. A.M.S. 106(1963)293-304.
+*R. Arens, ''Topologies for homeomorphism groups'', Amer. J. Math. 68 (1946), 593–610.
+[[Category:Algebraic topology]]
+[[Category:Homeomorphisms]]
+{{topology-stub}}

Glossary of cue sports terms: Difference between revisions

Revision as of 07:53, 16 January 2014

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