permutation

- group, ∞-group
- group object, group object in an (∞,1)-category
- abelian group, spectrum
- group action, ∞-action
- representation, ∞-representation
- progroup
- homogeneous space

A **permutation** is an automorphism in Set. More explicitly, a **permutation** of a set $X$ is an invertible function from $X$ to itself.

The group of permutations of $X$ (that is the automorphism group of $X$ in $Set$) is the **symmetric group** (or **permutation group**) on $X$ (a finite group). This group may be denoted $S_X$, $\Sigma_X$, or $X!$. When $X$ is the finite set $[n]$ with $n$ elements, one typically writes $S_n$ or $\Sigma_n$; note that this group has $n!$ elements.

In combinatorics, one often wants a slight generalisation. Given a natural number $r$, an **$r$-permutation** of $X$ is an injective function from $[r]$ to $X$, that is a list of $r$ distinct elements of $X$. Note that the number of $r$-permutations of $[n]$ is counted by the falling factorial $n(n-1)\dots(n-r+1)$. Then an $n$-permutation of $[n]$ is the same as a permutation of $[n]$, and the total number of such permutations is of course counted by the ordinary factorial $n!$. (That an injective function from $X$ to itself must be invertible characterises $X$ as a Dedekind-finite set.)

Every permutation $\pi : X \to X$ generates a cyclic subgroup $\langle \pi \rangle$ of the symmetric group $S_X$, and hence inherits a group action on $X$. The orbits of this action partition the set $X$ into a disjoint union of cycles, called the **cyclic decomposition** of the permutation $\pi$.

For example, let $\pi$ be the permutation on $[6] = \{0,\dots,5\}$ defined by

$\pi = \array{0 \mapsto 0 \\ 1 \mapsto 3 \\ 2 \mapsto 4 \\ 3 \mapsto 5 \\ 4 \mapsto 2 \\ 5 \mapsto 1}$

The domain of the permutation is partitioned into three $\langle\pi\rangle$-orbits

$[6] = \{0\} \cup \{1,3,5\} \cup \{2,4\}$

corresponding to the three cycles

$0 \underset{\pi}{\to} 0 \qquad
1 \underset{\pi}{\to} 3 \underset{\pi}{\to} 5 \underset{\pi}{\to} 1 \qquad
2 \underset{\pi}{\to} 4 \underset{\pi}{\to} 2$

Finally, we can express this more compactly by writing $\pi$ in cycle form, as the product $\pi = (0)(1\,3\,5)(2\,4)$.

One may regard the symmetric group $S_n$ as the general linear group in dimension $n$ on the field with one element $GL(n,\mathbb{F}_1)$.

- The symmetric group on 4 elements is isomorphic to the full tetrahedral group as well as to the orientation-preserving octahedral group.

Revised on August 31, 2015 05:38:24
by Noam Zeilberger
(195.83.213.132)