1.4 Group Action on a Set

Theorem

Let $G$ be a group. If $G$ acts on $S$ , then

The relation on $S$ defined by $x \sim x^{'}$ iff $gx = x^{'}$ for some $g \in G$ is an equivalent relationship.

For $x \in S$ , let $G_{x} = {h \in G : h x = x}$ . Then $G_{x}$ is a subgroup of $G$ .

Definition

Denote the equivalence class of $x \in S$ by $\overline{x} = {gx : g \in G}$ , and it is called the orbit of $x$ .

Examples. Let $G$ be a group and $H$ be a subgroup of $G$ .

$H$ acts on $G$ by conjugation. Then $H_{x} := {h \in H : h x h^{- 1} = x}$ is the centralizer of $x$ in $H$ .
$G$ acts on ${\mbox a ll s u b g ro u p so f G}$ by conjugation. Then $G_{K} := {g \in G : K^{g} = K}$ is the normalizer of $K$ .

Theorem

Let $G$ act on $S$ . Then $#∣ \overline{x} ∣ = [G : G_{x}]$ .

\begin{proof} Define a map ${\mbox a lll e f t cose t so f G_{x}} \to \overline{x}$ by $g G_{x} \mapsto gx$ . It is easy to show that this map is bijective. \end{proof}

Corollary

Let $G$ be a finite group. Consider $G$ acting on $G$ by conjugation.

number of elements in conjugate class of $x \in G$ is $[G : C_{G} (x)]$ .

Suppose $\overline{x_{1}}, \dots, \overline{x_{n}}$ are all distinct conjugacy classes of $G$ . Then $∣ G ∣ = \sum_{i = 1}^{n} [G : C_{G} (x_{i})]$ .

Let $K < G$ . Then the number of subgroup of $G$ conjugate to $K$ is $[G : N_{G} (K)]$ ,

Theorem

$G$ acting on $S$ induces a group homomorphism $G \to A (S)$ , where $A (S)$ is a group of all permutations of $S$ .

Cayley

Let $G$ be a group. Then there exists a group homomorphism $G ↪ A (G)$ . In particular, if $∣ G ∣ = n$ , then $G ↪ S_{n}$ ,

Notation. $A (G) = Perm (G)$ .

Remark.

$Inn (G) ⊲ Aut (G)$ and $Out (G) = Aut (G) / Inn (G)$
Class equation can be rewritten as $∣ G ∣ = ∣ C_{G} (G) ∣ + \sum_{x \neq \in C (G)} [G : C_{G} (x)]$ .

yhyquest

Explorer

1.4 Group Action on a Set

Graph View

Backlinks