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Section 14 Factor Groups

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Title: Section 14 Factor Groups


1
Section 14 Factor Groups
  • Factor Groups from Homomorphisms.
  • Theorem
  • Let ? G? G be a group homomorphism with kernel
    H. Then the cosets of H form a factor group, G/H,
    where (aH)(bH)(ab)H.
  • Also the map ?? G/H ? ?G defined by ?(aH)
    ?(a) is an isomorphism.
  • Both coset multiplication and ? are well defined,
    independent of the choices a and b from the
    cosets.

2
Examples
  • Example
  • Consider the map ? Z ? Zn, where ?(m) is the
    remainder when m is divided by n in accordance
    with the division algorithm. We know ? is a
    homomorphism, and Ker (?) n Z.
  • By previous theorem, the factor group Z / nZ is
    isomorphic to Zn. The cosets of n Z (nZ, 1n Z,
    ) are the residue classes modulo n.
  • Note Here is how to compute in a factor group
  • We can multiply (add) two cosets by choosing any
    two representative elements, multiplying (adding)
    them and finding the coset in which the resulting
    product (sum) lies.
  • Example in Z/5Z, we can add (25Z)(45Z)15Z
    by adding 2 and 4, finding 6 in 15Z, or adding
    27 and -16, finding 11 in 15Z.

3
Factor Groups from Normal Subgroups
  • Theorem
  • Let H be a subgroup of a group G. Then left coset
    multiplication is well defined by the equation
  • (aH)(bH)(abH)
  • If and only if H is a normal subgroup of G.

4
Definition
  • Corollary
  • Let H be a normal subgroup of G. Then the cosets
    of H form a group G/H under the binary operation
    (aH)(bH)(ab)H.
  • Proof. Exercise
  • Definition
  • The group G/H in the proceeding corollary is the
    factor group (or quotient group) of G by H.

5
Examples
  • Example
  • Since Z is an abelian group, nZ is a normal
    subgroup. Then we can construct the factor group
    Z/nZ with no reference to a homomorphism. In fact
    Z/ nZ is isomorphic to Zn.

6
Theorem
  • Theorem
  • Let H be a normal subgroup of G. Then ?? G ? G/H
    given by ?(x)xH is a homomorphism with kernel H.
  • Proof. Exercise

7
The Fundamental Homomorphism Theorem
  • Theorem (The Fundamental Homomorphism Theorem)
  • Let ? G ? G be a group homomorphism with kernel
    H. Then ?G is a group, and ? G/H ? ?G given
    by ?(gH) ?(g) is an isomorphism.
  • If ?? G ? G/H is the homomorphism given by
    ?(g)gH, then ?(g) ? ?(g) for each g?G.

?
G
?G
?
?
G/H
8
Example
  • In summary,
  • every homomorphism with domain G gives rise to a
    factor group G/H, and every factor group G/H
    gives rise to a homomorphism mapping G into G/H.
    Homomorphisms and factor groups are closely
    related.
  • Example Show that Z4 X Z2 / (0 X Z2) is
    isomorphic to Z4..
  • Note that ?1 Z4 X Z2 ? Z4 by ?1(x, y)x is a
    homomoorphism of Z4 X Z2 onto Z4 with kernel 0
    X Z2. By the Fundamental Homomorphism Theorem, Z4
    X Z2 / (0 X Z2) is isomorphic to Z4.

9
Normal Subgroups and Inner Automorphisms
  • Theorem
  • The following are three equivalent conditions for
    a subgroup H of a group G to be a normal subgroup
    of G.
  • ghg-1 ? H for all g ? G and h ? H.
  • ghg-1 H for all g ? G.
  • gH Hg for all g ? G.
  • Note Condition (2) of Theorem is often taken as
    the definition of a normal subgroup H of a group
    G.
  • Proof. Exercise.
  • Example Show that every subgroup H of an abelian
    group G is normal.
  • Note ghhg for all h ? H and all g ? G, so ghg-1
    h ? H for all h ? H and all g ? G.

10
Inner Automorphism
  • Definition
  • An isomorphism ? G ? G of a group G with itself
    is an automorphism of G. The automorphism ig G ?
    G , where Ig(x)gxg-1 for all x?G, is the inner
    automorphism of G by g. Performing Ig on x is
    callled conjugation of x by g.
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