In abstract algebra, a branch of mathematics, a group with operators or Ω-group is an algebraic structure that can be viewed as a group together with a set Ω that operates on the elements of the group in a special way.
Groups with operators were extensively studied by Emmy Noether and her school in the 1920s. She employed the concept in her original formulation of the three Noether isomorphism theorems.
A group with operators
(G,\Omega)
G=(G, ⋅ )
\Omega
G
\Omega x G → G:(\omega,g)\mapstog\omega
(g ⋅ h)\omega=g\omega ⋅ h\omega.
For each
\omega\in\Omega
g\mapstog\omega
\left(u\omega\right)\omega
\Omega
Given two groups G, H with same operator domain
\Omega
(G,\Omega)
(H,\Omega)
\phi:G\toH
\phi\left(g\omega\right)=(\phi(g))\omega
\omega\in\Omega
g\inG.
A subgroup S of G is called a stable subgroup,
\Omega
\Omega
s\omega\inS
s\inS
\omega\in\Omega.
In category theory, a group with operators can be defined as an object of a functor category GrpM where M is a monoid (i.e. a category with one object) and Grp denotes the category of groups. This definition is equivalent to the previous one, provided
\Omega
A morphism in this category is a natural transformation between two functors (i.e., two groups with operators sharing same operator domain M ). Again we recover the definition above of a homomorphism of groups with operators (with f the component of the natural transformation).
A group with operators is also a mapping
\Omega → \operatorname{End}Grp(G),
where
\operatorname{End}Grp(G)
The Jordan–Hölder theorem also holds in the context of groups with operators. The requirement that a group have a composition series is analogous to that of compactness in topology, and can sometimes be too strong a requirement. It is natural to talk about "compactness relative to a set", i.e. talk about composition series where each (normal) subgroup is an operator-subgroup relative to the operator set X, of the group in question.