In mathematics, a factor system (sometimes called factor set) is a fundamental tool of Otto Schreier’s classical theory for group extension problem.[1] It consists of a set of automorphisms and a binary function on a group satisfying certain condition (so-called cocycle condition). In fact, a factor system constitutes a realisation of the cocycles in the second cohomology group in group cohomology.
Suppose is a group and is an abelian group. For a group extension
1\toA\toX\toG\to1,
(g,a)*(h,b):=(gh,f(g,h)a\sigma(h)b).
If is trivial, then splits over, so that is the semidirect product of with .
If a group algebra is given, then a factor system f modifies that algebra to a skew-group algebra by modifying the group operation to .
Let G be a group and L a field on which G acts as automorphisms. A cocycle or (Noether) factor system[2] is a map c: G × G → L* satisfying
c(h,k)gc(hk,g)=c(h,kg)c(k,g).
Cocycles are equivalent if there exists some system of elements a : G → L* with
c'(g,h)=c(g,h)
h | |
(a | |
g |
ah
-1 | |
a | |
gh |
).
Cocycles of the form
c(g,h)=
h | |
a | |
g |
ah
-1 | |
a | |
gh |
are called split. Cocycles under multiplication modulo split cocycles form a group, the second cohomology group H2(G,L*).
Let us take the case that G is the Galois group of a field extension L/K. A factor system c in H2(G,L*) gives rise to a crossed product algebra[2] A, which is a K-algebra containing L as a subfield, generated by the elements λ in L and ug with multiplication
λug=ugλg,
uguh=ughc(g,h).
Equivalent factor systems correspond to a change of basis in A over K. We may write
A=(L,G,c).
The crossed product algebra A is a central simple algebra (CSA) of degree equal to [''L'' : ''K''].[3] The converse holds: every central simple algebra over K that splits over L and such that deg A = [''L'' : ''K''] arises in this way.[4] The tensor product of algebras corresponds to multiplication of the corresponding elements in H2. We thus obtain an identification of the Brauer group, where the elements are classes of CSAs over K, with H2.[5] [6]
Let us further restrict to the case that L/K is cyclic with Galois group G of order n generated by t. Let A be a crossed product (L,G,c) with factor set c. Let u = ut be the generator in A corresponding to t. We can define the other generators
u | |
ti |
=ui
and then we have un = a in K. This element a specifies a cocycle c by[2]
c(ti,tj)=\begin{cases}1&ifi+j<n,\ a&ifi+j\gen.\end{cases}
It thus makes sense to denote A simply by (L,t,a). However a is not uniquely specified by A since we can multiply u by any element λ of L* and then a is multiplied by the product of the conjugates of λ. Hence A corresponds to an element of the norm residue group K*/NL/KL*. We obtain the isomorphisms
\operatorname{Br}(L/K)\equiv
*/N | |
K | |
L/K |
L*\equivH2(G,L*).
. Nathan Jacobson . Finite-dimensional division algebras over fields . 0874.16002 . Berlin . . 3-540-57029-2 . 1996 .
. Irving Reiner . Maximal Orders . London Mathematical Society Monographs. New Series . 28 . . 2003 . 0-19-852673-3 . 1024.16008 .