In mathematics, specifically group theory, the index of a subgroup H in a group G is the number of left cosets of H in G, or equivalently, the number of right cosets of H in G.The index is denoted
|G:H|
[G:H]
(G:H)
|G|=|G:H||H|
|G:H|
For example, let
G=\Z
H=2\Z
2\Z
\Z
|\Z:2\Z|
|\Z:n\Z|=n
When G is finite, the formula may be written as
|G:H|=|G|/|H|
|H|
|G|
When G is infinite,
|G:H|
|\Z:2\Z|=2
|\R:\Z|
If N is a normal subgroup of G, then
|G:N|
G/N
G/N
|G:K|=|G:H||H:K|.
|G:H\capK|\le|G:H||G:K|,
with equality if
HK=G
|G:H\capK|
HK=G
|H:H\capK|\le|G:K|,
with equality if
HK=G
|H:H\capK|
HK=G
\varphi\colonG\toH
\varphi
|G:\operatorname{ker} \varphi|=|\operatorname{im} \varphi|.
|Gx|=|G:Gx|.
This is known as the orbit-stabilizer theorem.
gxg-1
x\inG
gHg-1
|G:\operatorname{Core}(H)|\le|G:H|!
where ! denotes the factorial function; this is discussed further below.
An
Sn,
\operatorname{SO}(n)
\operatorname{O}(n)
\Z ⊕ \Z
\{(x,y)\midxiseven\}, \{(x,y)\midyiseven\}, and \{(x,y)\midx+yiseven\}
\Zn
(pn-1)/(p-1)
(pn-1)
\Zn\to\Z/p\Z
Fn
(pn-1)/(p-1)
If H has an infinite number of cosets in G, then the index of H in G is said to be infinite. In this case, the index
|G:H|
A subgroup H of finite index in a group G (finite or infinite) always contains a normal subgroup N (of G), also of finite index. In fact, if H has index n, then the index of N will be some divisor of n! and a multiple of n; indeed, N can be taken to be the kernel of the natural homomorphism from G to the permutation group of the left (or right) cosets of H.Let us explain this in more detail, using right cosets:
The elements of G that leave all cosets the same form a group.If Hca ⊂ Hc ∀ c ∈ G and likewise Hcb ⊂ Hc ∀ c ∈ G, then Hcab ⊂ Hc ∀ c ∈ G. If h1ca = h2c for all c ∈ G (with h1, h2 ∈ H) then h2ca−1 = h1c, so Hca−1 ⊂ Hc.
Let us call this group A. Let B be the set of elements of G which perform a given permutation on the cosets of H. Then B is a right coset of A.
First let us show that if b∈B, then any other element b of B equals ab for some a∈A. Assume that multiplying the coset Hc on the right by elements of B gives elements of the coset Hd. If cb1 = d and cb2 = hd, then cb2b1−1 = hc ∈ Hc, or in other words b=ab for some a∈A, as desired. Now we show that for any b∈B and a∈A, ab will be an element of B. This is because the coset Hc is the same as Hca, so Hcb = Hcab. Since this is true for any c (that is, for any coset), it shows that multiplying on the right by ab makes the same permutation of cosets as multiplying by b, and therefore ab∈B.
What we have said so far applies whether the index of H is finite or infinte. Now assume that it is the finite number n. Since the number of possible permutations of cosets is finite, namely n!, then there can only be a finite number of sets like B. (If G is infinite, then all such sets are therefore infinite.) The set of these sets forms a group isomorphic to a subset of the group of permutations, so the number of these sets must divide n!. Furthermore, it must be a multiple of n because each coset of H contains the same number of cosets of A. Finally, if for some c ∈ G and a ∈ A we have ca = xc, then for any d ∈ G dca = dxc, but also dca = hdc for some h ∈ H (by the definition of A), so hd = dx. Since this is true for any d, x must be a member of A, so ca = xc implies that cac ∈ A and therefore A is a normal subgroup.
The index of the normal subgroup not only has to be a divisor of n!, but must satisfy other criteria as well. Since the normal subgroup is a subgroup of H, its index in G must be n times its index inside H. Its index in G must also correspond to a subgroup of the symmetric group S, the group of permutations of n objects. So for example if n is 5, the index cannot be 15 even though this divides 5!, because there is no subgroup of order 15 in S.
In the case of n = 2 this gives the rather obvious result that a subgroup H of index 2 is a normal subgroup, because the normal subgroup of H must have index 2 in G and therefore be identical to H. (We can arrive at this fact also by noting that all the elements of G that are not in H constitute the right coset of H and also the left coset, so the two are identical.) More generally, a subgroup of index p where p is the smallest prime factor of the order of G (if G is finite) is necessarily normal, as the index of N divides p! and thus must equal p, having no other prime factors. For example, the subgroup Z of the non-abelian group of order 21 is normal (see List of small non-abelian groups and Frobenius group#Examples).
An alternative proof of the result that a subgroup of index lowest prime p is normal, and other properties of subgroups of prime index are given in .
The group O of chiral octahedral symmetry has 24 elements. It has a dihedral D4 subgroup (in fact it has three such) of order 8, and thus of index 3 in O, which we shall call H. This dihedral group has a 4-member D2 subgroup, which we may call A. Multiplying on the right any element of a right coset of H by an element of A gives a member of the same coset of H (Hca = Hc). A is normal in O. There are six cosets of A, corresponding to the six elements of the symmetric group S3. All elements from any particular coset of A perform the same permutation of the cosets of H.
On the other hand, the group Th of pyritohedral symmetry also has 24 members and a subgroup of index 3 (this time it is a D2h prismatic symmetry group, see point groups in three dimensions), but in this case the whole subgroup is a normal subgroup. All members of a particular coset carry out the same permutation of these cosets, but in this case they represent only the 3-element alternating group in the 6-member S3 symmetric group.
Normal subgroups of prime power index are kernels of surjective maps to p-groups and have interesting structure, as described at Focal subgroup theorem: Subgroups and elaborated at focal subgroup theorem.
There are three important normal subgroups of prime power index, each being the smallest normal subgroup in a certain class:
pk
[G,G]
pk
Ep(G)\supseteqAp(G)\supseteqOp(G).
These groups have important connections to the Sylow subgroups and the transfer homomorphism, as discussed there.
An elementary observation is that one cannot have exactly 2 subgroups of index 2, as the complement of their symmetric difference yields a third. This is a simple corollary of the above discussion (namely the projectivization of the vector space structure of the elementary abelian group
G/Ep(G)\cong(Z/p)k
and further, G does not act on this geometry, nor does it reflect any of the non-abelian structure (in both cases because the quotient is abelian).
However, it is an elementary result, which can be seen concretely as follows: the set of normal subgroups of a given index p form a projective space, namely the projective space
P(\operatorname{Hom}(G,Z/p)).
In detail, the space of homomorphisms from G to the (cyclic) group of order p,
\operatorname{Hom}(G,Z/p),
Fp=Z/p.
(Z/p) x
P(\operatorname{Hom}(G,Z/p)):=(\operatorname{Hom}(G,Z/p))\setminus\{0\})/(Z/p) x
to normal index p subgroups. Conversely, a normal subgroup of index p determines a non-trivial map to
Z/p
1\inZ/p,
As a consequence, the number of normal subgroups of index p is
(pk+1-1)/(p-1)=1+p+ … +pk
for some k;
k=-1
p+1
For
p=2,
0,1,3,7,15,\ldots