Open main menu
Home
Random
Recent changes
Special pages
Community portal
Preferences
About Wikipedia
Disclaimers
Incubator escapee wiki
Search
User menu
Talk
Dark mode
Contributions
Create account
Log in
Editing
Group action
(section)
Warning:
You are not logged in. Your IP address will be publicly visible if you make any edits. If you
log in
or
create an account
, your edits will be attributed to your username, along with other benefits.
Anti-spam check. Do
not
fill this in!
== Examples == * The ''{{visible anchor|trivial}}'' action of any group {{math|''G''}} on any set {{math|''X''}} is defined by {{math|1=''g''β ''x'' = ''x''}} for all {{math|''g''}} in {{math|''G''}} and all {{math|''x''}} in {{math|''X''}}; that is, every group element induces the [[identity function|identity permutation]] on {{math|''X''}}.<ref>{{cite book|author=Eie & Chang |title=A Course on Abstract Algebra|year=2010|url={{Google books|plainurl=y|id=jozIZ0qrkk8C|page=144|text=trivial action}}|page=145}}</ref> * In every group {{math|''G''}}, left multiplication is an action of {{math|''G''}} on {{math|''G''}}: {{math|1=''g''β ''x'' = ''gx''}} for all {{math|''g''}}, {{math|''x''}} in {{math|''G''}}. This action is free and transitive (regular), and forms the basis of a rapid proof of [[Cayley's theorem]] β that every group is isomorphic to a subgroup of the symmetric group of permutations of the set {{math|''G''}}. * In every group {{math|''G''}} with subgroup {{math|''H''}}, left multiplication is an action of {{math|''G''}} on the set of cosets {{math|''G'' / ''H''}}: {{math|1=''g''β ''aH'' = ''gaH''}} for all {{math|''g''}}, {{math|''a''}} in {{math|''G''}}. In particular if {{math|''H''}} contains no nontrivial [[normal subgroups]] of {{math|''G''}} this induces an isomorphism from {{math|''G''}} to a subgroup of the permutation group of [[Degree of a permutation group|degree]] {{math|[''G'' : ''H'']}}. * In every group {{math|''G''}}, [[inner automorphism|conjugation]] is an action of {{math|''G''}} on {{math|''G''}}: {{math|1=''g''β ''x'' = ''gxg''<sup>β1</sup>}}. An exponential notation is commonly used for the right-action variant: {{math|1=''x<sup>g</sup>'' = ''g''<sup>β1</sup>''xg''}}; it satisfies ({{math|1=''x''<sup>''g''</sup>)<sup>''h''</sup> = ''x''<sup>''gh''</sup>}}. * In every group {{math|''G''}} with subgroup {{math|''H''}}, conjugation is an action of {{math|''G''}} on conjugates of {{math|''H''}}: {{math|1=''g''β ''K'' = ''gKg''<sup>β1</sup>}} for all {{math|''g''}} in {{math|''G''}} and {{math|''K''}} conjugates of {{math|''H''}}. * An action of {{math|'''Z'''}} on a set {{math|''X''}} uniquely determines and is determined by an [[automorphism]] of {{math|''X''}}, given by the action of 1. Similarly, an action of {{math|'''Z''' / 2'''Z'''}} on {{math|''X''}} is equivalent to the data of an [[involution (mathematics)|involution]] of {{math|''X''}}. * The symmetric group {{math|S<sub>''n''</sub>}} and its subgroups act on the set {{math|{{mset|1, ..., ''n''}}}} by permuting its elements * The [[symmetry group]] of a polyhedron acts on the set of vertices of that polyhedron. It also acts on the set of faces or the set of edges of the polyhedron. * The symmetry group of any geometrical object acts on the set of points of that object. * For a [[coordinate space]] {{math|''V''}} over a field {{math|''F''}} with group of units {{math|''F''*}}, the mapping {{math|''F''* Γ ''V'' β ''V''}} given by {{math|''a'' Γ (''x''<sub>1</sub>, ''x''<sub>2</sub>, ..., ''x''<sub>''n''</sub>) β¦ (''ax''<sub>1</sub>, ''ax''<sub>2</sub>, ..., ''ax''<sub>''n''</sub>)}} is a group action called [[scalar multiplication]]. * The automorphism group of a vector space (or [[graph theory|graph]], or group, or ring ...) acts on the vector space (or set of vertices of the graph, or group, or ring ...). * The general linear group {{math|GL(''n'', ''K'')}} and its subgroups, particularly its [[Lie subgroup]]s (including the special linear group {{math|SL(''n'', ''K'')}}, [[orthogonal group]] {{math|O(''n'', ''K'')}}, special orthogonal group {{math|SO(''n'', ''K'')}}, and [[symplectic group]] {{math|Sp(''n'', ''K'')}}) are [[Lie group]]s that act on the vector space {{math|''K''<sup>''n''</sup>}}. The group operations are given by multiplying the matrices from the groups with the vectors from {{math|''K''<sup>''n''</sup>}}. * The general linear group {{math|GL(''n'', '''Z''')}} acts on {{math|'''Z'''<sup>''n''</sup>}} by natural matrix action. The orbits of its action are classified by the [[greatest common divisor]] of coordinates of the vector in {{math|'''Z'''<sup>''n''</sup>}}. * The [[affine group]] acts [[#Notable properties of actions|transitively]] on the points of an [[affine space]], and the subgroup V of the affine group (that is, a vector space) has transitive and free (that is, ''regular'') action on these points;<ref>{{cite book|title=Geometry and topology|last=Reid|first=Miles|publisher=Cambridge University Press|year=2005|isbn=9780521613255|location=Cambridge, UK New York|pages=170}}</ref> indeed this can be used to give a definition of an [[Affine space#Definition|affine space]]. * The [[projective linear group]] {{math|PGL(''n'' + 1, ''K'')}} and its subgroups, particularly its Lie subgroups, which are Lie groups that act on the [[projective space]] {{math|'''P'''<sup>n</sup>(''K'')}}. This is a quotient of the action of the general linear group on projective space. Particularly notable is {{math|PGL(2, ''K'')}}, the symmetries of the projective line, which is sharply 3-transitive, preserving the [[cross ratio]]; the [[MΓΆbius group]] {{math|PGL(2, '''C''')}} is of particular interest. * The [[Isometry|isometries]] of the plane act on the set of 2D images and patterns, such as [[wallpaper group|wallpaper pattern]]s. The definition can be made more precise by specifying what is meant by image or pattern, for example, a function of position with values in a set of colors. Isometries are in fact one example of affine group (action).{{dubious|reason=The isometries of a space are a subgroup of the affine group of that space, but not an affine group in themselves|date=March 2015}} * The sets acted on by a group {{math|''G''}} comprise the [[Category (mathematics)|category]] of {{math|''G''}}-sets in which the objects are {{math|''G''}}-sets and the [[morphism]]s are {{math|''G''}}-set homomorphisms: functions {{math|''f'' : ''X'' β ''Y''}} such that {{math|1=''g''β (''f''(''x'')) = ''f''(''g''β ''x'')}} for every {{math|''g''}} in {{math|''G''}}. * The [[Galois group]] of a [[field extension]] {{math|''L'' / ''K''}} acts on the field {{math|''L''}} but has only a trivial action on elements of the subfield {{math|''K''}}. Subgroups of {{math|Gal(''L'' / ''K'')}} correspond to subfields of {{math|''L''}} that contain {{math|''K''}}, that is, intermediate field extensions between {{math|''L''}} and {{math|''K''}}. * The additive group of the [[real number]]s {{math|('''R''', +)}} acts on the [[phase space]] of "[[well-behaved]]" systems in [[classical mechanics]] (and in more general [[dynamical systems]]) by [[time translation]]: if {{math|''t''}} is in {{math|'''R'''}} and {{math|''x''}} is in the phase space, then {{math|''x''}} describes a state of the system, and {{math|''t'' + ''x''}} is defined to be the state of the system {{math|''t''}} seconds later if {{math|''t''}} is positive or {{math|−''t''}} seconds ago if {{math|''t''}} is negative. *The additive group of the real numbers {{math|('''R''', +)}} acts on the set of real [[Function of a real variable|functions of a real variable]] in various ways, with {{math|(''t''β ''f'')(''x'')}} equal to, for example, {{math|''f''(''x'' + ''t'')}}, {{math|''f''(''x'') + ''t''}}, {{math|''f''(''xe<sup>t</sup>'')}}, {{math|''f''(''x'')''e''<sup>''t''</sup>}}, {{math|''f''(''x'' + ''t'')''e<sup>t</sup>''}}, or {{math|''f''(''xe''<sup>''t''</sup>) + ''t''}}, but not {{math|''f''(''xe<sup>t</sup>'' + ''t'')}}. * Given a group action of {{math|''G''}} on {{math|''X''}}, we can define an induced action of {{math|''G''}} on the [[power set]] of {{math|''X''}}, by setting {{math|1=''g''β ''U'' = {''g''β ''u'' : ''u'' β ''U''}<nowiki/>}} for every subset {{math|''U''}} of {{math|''X''}} and every {{math|''g''}} in {{math|''G''}}. This is useful, for instance, in studying the action of the large [[Mathieu group]] on a 24-set and in studying symmetry in certain models of [[finite geometry|finite geometries]]. * The [[quaternion]]s with [[Norm of a quaternion|norm]] 1 (the [[versor]]s), as a multiplicative group, act on {{math|'''R'''<sup>3</sup>}}: for any such quaternion {{math|1=''z'' = cos ''Ξ±''/2 + '''v''' sin ''Ξ±''/2}}, the mapping {{math|1=''f''('''x''') = ''z'''''x'''''z''<sup>*</sup>}} is a counterclockwise rotation through an angle {{math|''Ξ±''}} about an axis given by a unit vector {{math|'''v'''}}; {{math|''z''}} is the same rotation; see [[quaternions and spatial rotation]]. This is not a faithful action because the quaternion {{math|β1}} leaves all points where they were, as does the quaternion {{math|1}}. * Given left {{math|''G''}}-sets {{math|''X''}}, {{math|''Y''}}, there is a left {{math|''G''}}-set {{math|''Y''{{i sup|''X''}}}} whose elements are {{math|''G''}}-equivariant maps {{math|''α'' : ''X'' Γ ''G'' β ''Y''}}, and with left {{math|''G''}}-action given by {{math|1=''g''β ''α'' = ''α'' β (id<sub>''X''</sub> Γ β''g'')}} (where "{{math|β''g''}}" indicates right multiplication by {{math|''g''}}). This {{math|''G''}}-set has the property that its fixed points correspond to equivariant maps {{math|''X'' β ''Y''}}; more generally, it is an [[exponential object]] in the category of {{math|''G''}}-sets.
Edit summary
(Briefly describe your changes)
By publishing changes, you agree to the
Terms of Use
, and you irrevocably agree to release your contribution under the
CC BY-SA 4.0 License
and the
GFDL
. You agree that a hyperlink or URL is sufficient attribution under the Creative Commons license.
Cancel
Editing help
(opens in new window)