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Revision as of 20:27, 1 November 2012 edit Rschwieb (talk \| contribs) Extended confirmed users 3,597 edits If you follow the link family (mathematics) you will see why set (mathematics) is much better. There is no reason to use "family." I am not even sure if anything but sets are used for this theory, so it seems safest to say "set." ← Previous edit		Latest revision as of 20:30, 18 May 2025 edit undo Beland (talk \| contribs) Autopatrolled, Administrators 259,161 edits m custom spacing in math formulas (via WP:JWB) Tag: JWB
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Line 1: {{Short description\|Concept in mathematics regarding sets operating on groups}} In [[abstract algebra]], a branch of ~~pure~~ [[mathematics]], ~~the [[algebraic structure]]~~a '''group with operators''' or Ω-'''group''' is an [[algebraic structure]] that can be viewed as a [[group (mathematics)\|group]] together with a [[set (mathematics)\|set]] Ω that operates on the elements of the group ~~[[endomorphism]]s~~in a special way. Groups with operators were extensively studied by [[Emmy Noether]] and her school in the 1920s. She employed the concept in her original formulation of the three [[Noether isomorphism ~~theorem~~theorems]]s. {{Algebraic structures~~\|cTopic=[[module (mathematics)~~\|Module~~]]-like structures~~}} == Definition == A '''group with operators''' <math>(''G'', ~~<math>~~\Omega)</math>) can be defined{{sfn\|Bourbaki\|1974\|p=31}} as a group ''<math>G'' = (G, \cdot)</math> together with an action of a set <math>\Omega</math> on ''<math>G'' </math>: : <math>\ \Omega \times G \rightarrow G : (\omega , g) \mapsto g^{\omega}</math> ~~which~~that is [[distributive ~~relatively~~property\|distributive]] relative to the group law : : <math>(g \cdot ~~(gh~~h)^{\omega} = g^{\omega} \cdot h^{\omega}.</math> ~~For each <math>\omega \in \Omega </math>, the application~~ ~~:<math>\ g \mapsto g^{\omega}</math>~~ is then an endomorphism of ''G''. From this, it results that a Ω-group can also be viewed as a group ''G'' with an indexed set <math>(u_{\omega})_{\omega \in \Omega}</math> of endomorphisms of ''G''.▼ ▲For each <math>\omega \in \Omega </math>, the application <math>g \mapsto g^\omega</math> is then an [[Group homomorphism#Types\|endomorphism]] of ''G''. From this, it results that a Ω-group can also be viewed as a group ''G'' with an [[indexed ~~set~~family]] <math>\left(u_{\omega}\right)_{\omega \in \Omega}</math> of endomorphisms of ''G''. <math>\Omega</math> is called the '''operator ___domain'''. The associate [[endomorphisms]]{{sfn\|Bourbaki\|1974\|pp=30-31}} are called the '''homotheties''' of ''G''.▼ ▲<math>\Omega</math> is called the '''operator ___domain'''. The associate [[endomorphisms]]{{sfn\|Bourbaki\|1974\|pp=~~30-31~~30–31}} are called the '''homotheties''' of ''G''. ~~We denote the image of a group element ''g'' under a function <math>\omega</math> with <math>g^\omega</math>. The distributivity can then be expressed as~~ ~~:<math>\forall \omega \in \Omega, \forall g,h \in G \quad (gh)^{\omega} = g^{\omega}h^{\omega} .</math>~~ Given two groups ''G'', ''H'' with same operator ___domain <math>\Omega</math>, a '''homomorphism''' of groups with operators from <math>(G, \Omega)</math> to <math>(H, \Omega)</math> is a [[group homomorphism]] ~~''f'':''G''~~<math>\phi: G \to H</math>~~''H''~~ satisfying : <math>\~~forall~~phi\left(g^\omega\right) = (\phi(g))^\omega</math> for all <math>\omega \in \Omega,</math> ~~\forall~~and <math>g \in G ~~: f(g^\omega)=(f(g))^\omega~~.</math> A [[subgroup]] ''S'' of ''G'' is called a '''stable subgroup''', '''<math>\~~omega~~Omega</math>-subgroup''' or '''<math>\Omega</math>-invariant subgroup''' if it respects the homotheties, that is : <math>s^\~~forall s~~omega \in S,</math> ~~\forall~~for ~~\omega~~all <math>s \in ~~\Omega~~S</math> :and s^<math>\omega \in S\Omega.</math> == Category-theoretic remarks == In [[category theory]], a '''group with operators''' can be defined{{sfn\|Mac Lane\|1998\|p=41}} as an [[object (category theory)\|object]] of a [[functor category]] '''Grp'''<sup>''M''</sup> where ''M'' is a [[monoid]] (''i.e.~~'',~~ a [[category (mathematics)\|category]] with one object) and '''Grp''' denotes the [[category of groups]]. This definition is equivalent to the previous one, provided <math>\Omega</math> is a monoid (~~otherwise~~if not, we may expand it to include the [[identity function\|identity]] and all [[function composition\|compositions]]). A [[morphism]] in this category is a [[natural transformation]] between two ~~functors~~[[functor]]s (''i.e.'', two groups with operators sharing same operator ___domain ''M''{{hairsp}}). Again we recover the definition above of a homomorphism of groups with operators (with ''f'' the [[~~Natural_Transformation~~natural transformation#Definition\|component]] of the natural transformation). A group with operators is also a mapping :<math>\Omega \rightarrow \operatorname{End}_{\mathbf{Grp}}(G),</math> where <math>\operatorname{End}_{\mathbf{Grp}}(G)</math> is the set of group ~~[[endomorphism]]s~~endomorphisms of ''G''. == Examples == * Given any group ''G'', (''G'', ∅) is trivially a group with operators * Given ana [[module (mathematics)\|module]] ''RM''- over a [[~~module~~ring (mathematics)\|~~module~~ring]] ''MR'', ''R'' acts by [[scalar multiplication]] on the underlying ~~Abelian~~[[abelian group]] of ''M'', so (''M'', ''R'') is a group with operators. * As a special case of the above, every [[vector space]] over a [[field (mathematics)\|field]] ''kK'' is a group with operators (''V'', ''kK''). ==Applications== The [[Jordan–Hölder theorem]] also holds in the context of ~~operator~~ groups with operators. The requirement that a group have a [[composition series]] is analogous to that of [[compact space\|compactness]] in [[topology]], and can sometimes be too strong a requirement. It is natural to talk about "compactness relative to a set", i.e. talk about [[composition series]] where each ([[Normal subgroup\|normal]]) subgroup is an operator-subgroup relative to the operator set ''X'', of the group in question.▼ ▲The [[Jordan–Hölder theorem]] also holds in the context of operator groups. The requirement that a group have a [[composition series]] is analogous to that of [[compact space\|compactness]] in [[topology]], and can sometimes be too strong a requirement. It is natural to talk about "compactness relative to a set", i.e. talk about [[composition series]] where each (normal) subgroup is an operator-subgroup relative to the operator set ''X'', of the group in question. ==See also== * [[Group action (mathematics)\|Group action]] ==Notes== Line 51 ⟶ 47: == References == {{cite book ~~\| ref=harv~~ \| last=Bourbaki \| first=Nicolas \| title=Elements of Mathematics : Algebra I Chapters ~~1-3~~1–3 \| publisher=Hermann \| year=1974 \| isbn=2-7056-5675-8 \| url-access=registration \| url=https://archive.org/details/algebra0000bour }} {{cite book ~~\| ref=harv~~ \| last=Bourbaki \| first=Nicolas \| title=Elements of Mathematics : Algebra I Chapters ~~1-3~~1–3 \| publisher=Springer-Verlag \| year=1998 \| isbn=3-540-64243-9}} *{{cite book ~~\| ref=harv~~ \| last=Mac Lane \| first=Saunders \| title=Categories for the Working Mathematician \| publisher=Springer-Verlag \| year=1998 \| isbn=0-387-98403-8}} [[Category:Group actions]] [[Category:Universal algebra]] ~~[[fr:Groupe à opérateurs]]~~ ~~[[ja:作用を持つ群]]~~ ~~[[pl:Grupa z operatorami]]~~