https://wiki.sarg.dev/index.php?action=history&feed=atom&title=Loop_groupLoop group - Revision history2026-04-24T20:55:15ZRevision history for this page on the wikiMediaWiki 1.44.2https://wiki.sarg.dev/index.php?title=Loop_group&diff=787668&oldid=previmported>ChaoticVermillion: Importing Wikidata short description: "Loop space over a Lie group"2025-09-17T09:25:22Z<p>Importing Wikidata <a href="https://en.wikipedia.org/wiki/Short_description" class="extiw" title="wikipedia:Short description">short description</a>: "Loop space over a Lie group"</p>
<p><b>New page</b></p><div>{{Short description|Loop space over a Lie group}}<br />
{{for|groups of actors involved in re-recording movie dialogue during post-production (commonly known in the entertainment industry as "loop groups")|Dubbing (filmmaking)}}<br />
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{{Group theory sidebar |Topological}}<br />
{{Lie groups |Other}}<br />
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In [[mathematics]], a '''loop group''' (not to be confused with a [[Quasigroup#Loops|loop]]) is a [[group (mathematics)|group]] of [[loop (topology)|loop]]s in a [[topological group]] ''G'' with multiplication defined [[pointwise]].<br />
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==Definition==<br />
In its most general form a loop group is a group of [[continuous function (topology)|continuous mappings]] from a [[manifold]] {{math|''M''}} to a topological group {{math|''G''}}.<br />
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More specifically,{{sfn|De Kerf|Bäuerle|Ten Kroode|1997}} let {{math|''M'' {{=}} ''S''<sup>1</sup>}}, the circle in the [[complex plane]], and let {{math|''LG''}} denote the [[Topological space|space]] of continuous maps {{math|''S''<sup>1</sup> → ''G''}}, i.e.<br />
:<math>LG = \{\gamma:S^1 \to G|\gamma \in C(S^1, G)\},</math><br />
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equipped with the [[compact-open topology]]. An element of {{math|''LG''}} is called a ''loop'' in {{math|''G''}}. <br />
Pointwise multiplication of such loops gives {{math|''LG''}} the structure of a topological group. Parametrize {{math|''S''<sup>1</sup>}} with {{mvar|θ}},<br />
:<math>\gamma:\theta \in S^1 \mapsto \gamma(\theta) \in G,</math><br />
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and define multiplication in {{math|''LG''}} by<br />
:<math>(\gamma_1 \gamma_2)(\theta) \equiv \gamma_1(\theta)\gamma_2(\theta).</math><br />
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[[Associativity]] follows from associativity in {{math|''G''}}. The inverse is given by<br />
:<math>\gamma^{-1}:\gamma^{-1}(\theta) \equiv \gamma(\theta)^{-1},</math><br />
and the identity by<br />
:<math>e:\theta \mapsto e \in G.</math><br />
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The space {{math|''LG''}} is called the '''free loop group''' on {{math|''G''}}. A loop group is any [[subgroup]] of the free loop group {{math|''LG''}}.<br />
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==Examples==<br />
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An important example of a loop group is the group <br />
:<math>\Omega G \,</math><br />
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of based loops on {{math|''G''}}. It is defined to be the [[kernel (algebra)|kernel]] of the evaluation map <br />
:<math>e_1: LG \to G,\gamma\mapsto \gamma(1)</math>,<br />
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and hence is a [[closed set|closed]] [[normal subgroup]] of {{math|''LG''}}. (Here, {{math|''e''<sub>1</sub>}} is the map that sends a loop to its value at <math>1 \in S^1</math>.) Note that we may embed {{math|''G''}} into {{math|''LG''}} as the subgroup of constant loops. Consequently, we arrive at a [[split exact sequence]] <br />
:<math>1\to \Omega G \to LG \to G\to 1</math>.<br />
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The space {{math|''LG''}} splits as a [[semi-direct product]], <br />
:<math>LG = \Omega G \rtimes G</math>.<br />
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We may also think of {{math|Ω''G''}} as the [[loop space]] on {{math|''G''}}. From this point of view, {{math|Ω''G''}} is an [[H-space]] with respect to concatenation of loops. On the face of it, this seems to provide {{math|Ω''G''}} with two very different product maps. However, it can be shown that concatenation and pointwise multiplication are [[homotopy|homotopic]]. Thus, in terms of the homotopy theory of {{math|Ω''G''}}, these maps are interchangeable.<br />
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Loop groups were used to explain the phenomenon of [[Bäcklund transform]]s in [[soliton]] equations by [[Chuu-Lian Terng]] and [[Karen Uhlenbeck]].{{sfn|Terng|Uhlenbeck|2000}}<br />
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== See also ==<br />
*[[Loop space]]<br />
*[[Loop algebra]]<br />
*[[Quasigroup]]<br />
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== Notes ==<br />
{{reflist}}<br />
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== References ==<br />
*{{citation |doi=10.1016/S0925-8582(97)80010-3 |chapter=Representations of loop algebras |title=Lie Algebras - Finite and Infinite Dimensional Lie Algebras and Applications in Physics |series=Studies in Mathematical Physics |date=1997 |volume=7 |pages=365–429 |isbn=978-0-444-82836-1 |editor1-first=E.A. |editor1-last=De Kerf |editor2-first=G.G.A. |editor2-last=Bäuerle |editor3-first=A.P.E. |editor3-last=Ten Kroode }}<br />
*{{citation|mr=0900587|last1=Pressley|first1=Andrew|last2=Segal|first2=Graeme|authorlink2=Graeme Segal|title=Loop groups|series=Oxford Mathematical Monographs. Oxford Science Publications|publisher=[[Oxford University Press]]|location=New York|year=1986|isbn=978-0-19-853535-5|url=https://books.google.com/books?id=MbFBXyuxLKgC}}<br />
*{{citation |last1=Terng |first1=Chuu-Lian |first2=Karen |last2=Uhlenbeck |title=Geometry of solitons |journal=Notices of the American Mathematical Society |volume=47 |issue=1 |date=2000 |pages=17–25 |url=https://www.ams.org/notices/200001/fea-terng.pdf }}<br />
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[[Category:Topological groups]]<br />
[[Category:Solitons]]</div>imported>ChaoticVermillion