Normal subgroup: Difference between revisions

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In [[group theory]], a branch of [[mathematics]], a '''normal [[subgroup]]''', also known as '''invariant subgroup''', or '''normal divisor''', is a (proper or improper) subgroup ''H'' of the [[group]] ''G'' that is invariant under [[conjugation]] by all elements of ''G''.


==Definition==
Two elements,  ''a′'' and ''a'',  of  ''G'' are said to be conjugate by ''g'' ∈ ''G'',  if
''a&prime;''  = ''g a g<sup>&minus;1</sup>''. Clearly, ''a''  = ''g<sup>&minus;1</sup> a&prime; g'', so that conjugation is symmetric; ''a'' and ''a&prime;'' are conjugate partners.
 
If for all ''h'' &isin; ''H''  and all ''g'' &isin; ''G'' it holds that:  ''g h g<sup>&minus;1</sup>'' &isin; ''H'',  then ''H'' is a normal subgroup of ''G'', (also expressed as "''H'' is invariant in ''G''").  That is, with ''h'' in ''H'' all conjugate partners of ''h'' are also in ''H''.
==Equivalent definitions==


A [[subgroup]] ''H'' of a [[group]] ''G'' is termed '''normal''' if the following equivalent conditions are satisfied:
A [[subgroup]] ''H'' of a [[group]] ''G'' is termed '''normal''' if the following equivalent conditions are satisfied:
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# Every [[inner automorphism]] of ''G'' sends ''H'' to within itself
# Every [[inner automorphism]] of ''G'' sends ''H'' to within itself
# Every [[inner automorphism]] of ''G'' restricts to an automorphism of ''H''
# Every [[inner automorphism]] of ''G'' restricts to an automorphism of ''H''
# The left [[coset]]s and right [[coset]]s of ''H'' are always equal: <math>x H = H x</math>
# The left [[coset]]s and right [[coset]]s of ''H'' are always equal: <math>x H = H x</math>. (This is often expressed as: "''H'' is simultaneously left- and right-invariant").
 
==Some elementary examples and nonexamples==


==Some elementary examples and counterexamples==
===Klein's Vierergruppe in ''S''<sub>4</sub>===
The set of all [[permutation]]s of 4 elements forms the symmetric group ''S''<sub>4</sub>, which is of order of 4! = 24. The group of the following four permutations is a subgroup and has the structure of [[Felix Klein]]'s [[Vierergruppe]]:
: ''V''<sub>4</sub> &equiv; {(1), (12)(34), (13)(24), (14)(23)}
It is easily verified that ''V''<sub>4</sub> is a normal subgroup of  ''S''<sub>4</sub>. [Conjugation preserves the cycle structure (..)(..) and ''V''<sub>4</sub> contains all elements with this structure.]
===All subgroups in Abelian groups===
===All subgroups in Abelian groups===


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In particular, subgroups like the [[centre of a group|center]], the [[commutator subgroup]], the [[Frattini subgroup]] are examples of characteristic, and hence normal, subgroups.
In particular, subgroups like the [[centre of a group|center]], the [[commutator subgroup]], the [[Frattini subgroup]] are examples of characteristic, and hence normal, subgroups.


===A smallest non-example===
===A smallest counterexample===


The smallest example of a non-normal subgroup is a subgroup of order two in the symmetric group on three elements. Explicitly, we can take the cyclic subgroup of order two generated by the 2-cycle <math>(12)</math> in the symmetric group of permutations on symbols <math>1,2,3</math>.
The smallest example of a non-normal subgroup is a subgroup of order two in the symmetric group on three elements. Explicitly, we can take the cyclic subgroup of order two generated by the 2-cycle <math>(12)</math> in the symmetric group of permutations on symbols <math>1,2,3</math>.
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:<math> (Nx)^{-1} = N x^{-1} \, </math>
:<math> (Nx)^{-1} = N x^{-1} \, </math>


and the coset <math>N = N1</math> as [[identity element]].  It is easy to check that these define a group structure on the set of cosets and that the '''quotient map''' <math>q_N : x \mapsto N x</math> is a [[group homomorphism]].
and the coset <math>N = N1</math> as [[identity element]].  It is easy to check that these define a group structure on the set of cosets and that the '''quotient map''' <math>q_N : x \mapsto N x</math> is a [[group homomorphism]]. Because of this property ''N'' is sometimes called a ''normal divisor'' of ''G''.


===First Isomorphism Theorem===
===First Isomorphism Theorem===

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In group theory, a branch of mathematics, a normal subgroup, also known as invariant subgroup, or normal divisor, is a (proper or improper) subgroup H of the group G that is invariant under conjugation by all elements of G.

Two elements, a′ and a, of G are said to be conjugate by gG, if a′ = g a g−1. Clearly, a = g−1 a′ g, so that conjugation is symmetric; a and a′ are conjugate partners.

If for all hH and all gG it holds that: g h g−1H, then H is a normal subgroup of G, (also expressed as "H is invariant in G"). That is, with h in H all conjugate partners of h are also in H.

Equivalent definitions

A subgroup H of a group G is termed normal if the following equivalent conditions are satisfied:

  1. Given any and , we have
  2. H occurs as the kernel of a homomorphism from G. In other words, there is a homomorphism such that the inverse image of the identity element of K is H.
  3. Every inner automorphism of G sends H to within itself
  4. Every inner automorphism of G restricts to an automorphism of H
  5. The left cosets and right cosets of H are always equal: . (This is often expressed as: "H is simultaneously left- and right-invariant").

Some elementary examples and counterexamples

Klein's Vierergruppe in S4

The set of all permutations of 4 elements forms the symmetric group S4, which is of order of 4! = 24. The group of the following four permutations is a subgroup and has the structure of Felix Klein's Vierergruppe:

V4 ≡ {(1), (12)(34), (13)(24), (14)(23)}

It is easily verified that V4 is a normal subgroup of S4. [Conjugation preserves the cycle structure (..)(..) and V4 contains all elements with this structure.]

All subgroups in Abelian groups

In an Abelian group, every subgroup is normal. This is because if is an Abelian group, and , then .

More generally, any subgroup inside the center of a group is normal.

It is not, however, true that if every subgroup of a group is normal, then the group must be Abelian. A counterexample is the quaternion group.

All characteristic subgroups

A characteristic subgroup of a group is a subgroup which is invariant under all automorphisms of the whole group. Characteristic subgroups are normal, because normality requires invariance only under inner automorphisms, which are a particular kind of automorphism.

In particular, subgroups like the center, the commutator subgroup, the Frattini subgroup are examples of characteristic, and hence normal, subgroups.

A smallest counterexample

The smallest example of a non-normal subgroup is a subgroup of order two in the symmetric group on three elements. Explicitly, we can take the cyclic subgroup of order two generated by the 2-cycle in the symmetric group of permutations on symbols .

Properties

The intersection of any family of normal subgroups is again a normal subgroup. We can therefore define the normal subgroup generated by a subset S of a group G to be the intersection of all normal subgroups of G containing S.

Quotient group

The quotient group of a group G by a normal subgroup N is defined as the set of (left or right) cosets:

with the the group operations

and the coset as identity element. It is easy to check that these define a group structure on the set of cosets and that the quotient map is a group homomorphism. Because of this property N is sometimes called a normal divisor of G.

First Isomorphism Theorem

The First Isomorphism Theorem for groups states that if is a group homomorphism then the kernel of f, say K, is a normal subgroup of G, and the map f factors through the quotient map and an injective homomorphism i:


External links