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In group theory, a subgroup of a group is a subset which is itself a group with respect to the same operations.

Formally, a subset S of a group G is a subgroup if it satisfies the following conditions:

The identity element of G is an element of S;
S is closed under taking inverses, that is, $x\in S\Rightarrow x^{-1}\in S$ ;
S is closed under the group operation, that is, $x,y\in S\Rightarrow xy\in S$ .

These correspond to the conditions on a group, with the exception that the associative property is necessarily inherited.

It is possible to replace these by the single closure property that S is non-empty and $x,y\in S\Rightarrow xy^{-1}\in S$ .

The group itself and the set consisting of the identity element are always subgroups.

Particular classes of subgroups include:

Characteristic subgroup [r]: A subgroup which is mapped to itself by any automorphism of the whole group. ^[e]
Essential subgroup [r]: A subgroup of a group which has non-trivial intersection with every other non-trivial subgroup. ^[e]
Normal subgroup [r]: Subgroup N of a group G where every expression g-1ng is in N for every g in G and every n in N. ^[e]

Specific subgroups of a given group include:

Centre of a group [r]: The subgroup of a group consisting of all elements which commute with every element of the group. ^[e]
Commutator subgroup [r]: The subgroup of a group generated by all commutators. ^[e]
Frattini subgroup [r]: The intersection of all maximal subgroups of a group. ^[e]

Cosets

The left cosets of a subgroup H of a group G are the subsets of G of the form x H for a particular element x of G:

xH=\{xh:h\in H\}.\,

The right cosets H x are defined similarly:

Hx=\{hx:h\in H\}.\,

The left cosets partition the group G, any two cosets $xH$ and $yH$ are either equal or disjoint. This may be proved directly, or deduced from the observation that the left cosets are the equivalence classes for the equivalence relation ${\stackrel {H}{\sim }}$ defined by

x{\stackrel {H}{\sim }}y\Leftrightarrow x^{-1}y\in H.\,

Similar remarks apply to the right cosets. A subgroup is normal if the left cosets agree with the right cosets for all elements.

References

Marshall Hall jr (1959). The theory of groups. New York: Macmillan, 7-8.

@@ Line 17: / Line 17: @@
 {{r|Normal subgroup}}
+Specific subgroups of a given group include:
-Specific subgroups on a given group include:
 {{r|Centre of a group}}
 {{r|Commutator subgroup}}
 {{r|Frattini subgroup}}
+==Cosets==
+The left cosets of a subgroup ''H'' of a group ''G'' are the subsets of ''G'' of the form ''x'' ''H'' for a particular element ''x'' of ''G'':
+:<math> x H = \{ x h : h \in H \} .\,</math>
+The right cosets ''H'' ''x'' are defined similarly:
+:<math> H x = \{ h x : h \in H \} .\,</math>
+The left cosets [[partition]] the group ''G'', any two cosets <math>x H</math> and <math>y H</math> are either equal or [[disjoint sets|disjoint]].  This may be proved directly, or deduced from the observation that the left cosets are the [[equivalence class]]es for the [[equivalence relation]] <math>\stackrel{H}{\sim}</math> defined by
+:<math>x \stackrel{H}{\sim} y  \Leftrightarrow x^{-1}y \in H . \,</math>
+Similar remarks apply to the right cosets.  A subgroup is [[normal subgroup|normal]] if the left cosets agree with the right cosets for all elements.
 ==References==
 * {{cite book | author=Marshall Hall jr | title=The theory of groups | publisher=Macmillan | location=New York | year=1959 | pages=7-8 }}

Subgroup: Difference between revisions

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