Regular group

There are several (different) notions of regularity in group theory. Most are not intrinsic to a group itself, but pertain to a group acting on something.

Regular group of permutations.

Let $G$ be a finite group acting on a set $\Omega$, i.e. a permutation group (group of permutations). The permutation group $G$ is said to be regular if for all $a \in \Omega$, $G_a = \{g\in G: ga=a\}$, the stabilizer subgroup at $a$, is trivial.

In the older mathematical literature, and in physics, a slightly stronger notion is used: $G$ is transitive (i.e., for all $a , b \in \Omega$ there is a $g \in G$ such that $g a = b$) and $\operatorname{degree}( G , \Omega ) = \operatorname { order } ( G )$, where $\operatorname{degree}( G , \Omega )$ is the number of elements of $\Omega$ and $\operatorname{order}( G )$ is, of course, the number of elements of $G$. It is easy to see that a transitive regular permutation group satisfies this condition. Inversely, a transitive permutation group for which $\operatorname{degree}( G , \Omega ) = \operatorname { order } ( G )$ is regular.

A permutation is regular if all cycles in its canonical cycle decomposition have the same length. If $G$ is a transitive regular permutation group, then all its elements, regarded as permutations on $\Omega$, are regular permutations.

An example of a transitive regular permutation group is the Klein $4$-group $G = V _ { 4 } = \{ ( 1 ) , ( 12 ) ( 34 ) , ( 13 ) ( 24 ) , ( 14 ) ( 23 ) \}$ of permutations of $\Omega = \{ 1,2,3,4 \}$.

The regular permutation representation of a group $G$ defined by left (respectively, right) translation $g : h \mapsto g h$ (respectively, $g : h \mapsto h g ^ { - 1 }$) exhibits $G$ as a regular permutation group on $\Omega = G$.

Regular group of automorphisms.

Let $G$ act on a group $A$ by means of automorphisms (i.e., there is given a homomorphism of groups $G \rightarrow \operatorname { Aut } ( A )$, $\alpha \mapsto a ^ { g }$, $a \in A$). $G$ is said to act fixed-point-free if for all $a \in A$ there is a $g \in G$ such that $a ^ { g } \neq a$, i.e. there is no other global fixed point except the obvious and necessary one $1 \in A$. There is a conjecture that if $G$ acts fixed-point-free on $A$ and $( | G | , | A | ) = 1$, then $A$ is solvable, [a7]; see also Fitting length for some detailed results in this direction.

$G$ is said to be a regular group of automorphisms of $A$ if for all $1 \neq g \in G$ only the identity element of $A$ is left fixed by $g$, i.e. $C _ { A } ( g ) = \{ a \in A : a ^ { g } = a \} = \{ 1 \}$ for all $g \neq 1$. Some authors use the terminology "fixed-point-free" for the just this property.

Regular $p$-group.

A $p$-group is said to be regular if $( x y ) ^ { p } = x ^ { p } y ^ { p } z$, where $z$ is an element of the commutator subgroup of the subgroup generated by $x$ and $y$, i.e. $z$ is a product of iterated commutators of $x$ and $y$. See [a5].

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