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In mathematics, the symmetric group is the group of all permutations of a set, that is, of all invertible functions from a set to itself. It is a central object of study in group theory.

Definition

If ${\displaystyle n}$ is a positive integer, the symmetric group on ${\displaystyle n}$ "letters" (often denoted ${\displaystyle S_{n}}$) is the group formed by all bijections from a set ${\displaystyle S}$ to itself (under the operation of function composition), where ${\displaystyle S}$ is an ${\displaystyle n}$-element set. It is customary to take ${\displaystyle S}$ to be the set of integers from ${\displaystyle 1}$ to ${\displaystyle n}$, but this is not strictly necessary. The bijections which are elements of the symmetric group are called permutations.

Note that this means the identity element of the group is the identity map on ${\displaystyle S}$, which is the map sending each element of ${\displaystyle S}$ to itself.

The order of ${\displaystyle S_{n}}$ is given by the factorial function ${\displaystyle n!}$.

Cycle Decomposition

Any permutation of a finite set can be written as a product of permutations called cycles. A cycle ${\displaystyle \rho }$ acting on ${\displaystyle S}$ fixes all the elements of S outside a nonempty subset ${\displaystyle C}$ of ${\displaystyle S}$. On ${\displaystyle C}$, the action of ${\displaystyle \rho }$ is as follows: for some indexing ${\displaystyle C=\{c_{1},\ldots ,c_{k}\}}$ of the elements of ${\displaystyle C}$, ${\displaystyle \rho }$ sends ${\displaystyle c_{i}}$ to ${\displaystyle c_{i+1}}$ for all ${\displaystyle 1\leq i\leq k-1}$ and sends ${\displaystyle c_{k}}$ to ${\displaystyle c_{1}}$. Then one writes

${\displaystyle \rho =\left(c_{1},\ldots ,c_{k}\right)}$

(Sometimes the commas are omitted.) If k > 1, such a ${\displaystyle \rho }$ is called a k-cycle.

For example, the permutation of the integers from 1 to 4 sending ${\displaystyle i}$ to ${\displaystyle 5-i}$ for all ${\displaystyle 1\leq i\leq 4}$ can be denoted ${\displaystyle (1,4)(2,3)}$.

If ${\displaystyle C}$ is a one-element set, then its element is a fixed point of the permutation. Fixed points are often omitted from permutations written in cycle notation, since any ${\displaystyle \rho }$ cycling the elements of ${\displaystyle C}$ as discussed above would be the identity permutation.

The cycle shape of an element is the list of cycle lengths written in decreasing order.

The order of a permutation is the least common multiple of the cycle lengths in the cycle decomposition.

Conjugacy

We recall that the conjugate of a group element ${\displaystyle \alpha }$ by an element ${\displaystyle \beta }$ is ${\displaystyle \alpha ^{\beta }=\beta ^{-1}\alpha \beta }$. Conjugation of a permutation is particularly simple to express in terms of cycle decomposition. If

${\displaystyle \alpha =\left(a_{1}\ldots a_{k}\right)\left(b_{1}\ldots b_{l}\right)\cdots \,}$

then the conjugate

${\displaystyle \alpha ^{\beta }=\left(\beta (a_{1})\ldots \beta (a_{k})\right)\left(\beta (b_{1})\ldots \beta (b_{l})\right)\cdots .\,}$

Two elements are conjugate if and only if they have the same cycle shape. The number of conjugacy classes of S_n is thus equal to ${\displaystyle p(n)}$, the number of partitions of n.

Permutational Parity

A 2-cycle is called a transposition. A cycle can be written as a product of transpositions, ${\displaystyle (a~b~c~\ldots ~z)=(a~b)(a~c)\cdots (a~z)}$, and hence every permutation in ${\displaystyle S_{n}}$, for n > 1, can be written as a product of transpositions. A permutation of n points is then called even if it can be written as the product of an even number of transpositions and odd if it can be written as the product of an odd number of transpositions. The nontrivial fact about this terminology is that it is well-defined; that is, no permutation is both even and odd.

The even permutations in ${\displaystyle S_{n}}$ form a subgroup of ${\displaystyle S_{n}}$. This subgroup is called the alternating group on n letters and denoted ${\displaystyle A_{n}}$. In fact, ${\displaystyle A_{n}}$ is always a normal subgroup of ${\displaystyle S_{n}}$.

The order of ${\displaystyle A_{n}}$ is ${\displaystyle {\frac {n!}{2}}}$.

Notes on the Structure of the Symmetric Group

${\displaystyle S_{n}}$ has proper normal subgroups if and only if n >= 3. Then the only proper normal subgroup of ${\displaystyle S_{n}}$ is ${\displaystyle A_{n}}$, unless n=4. When n=4, there is an additional proper normal subgroup, often denoted V, consisting of the identity permutation and the permutations (1,2)(3,4), (1,3)(2,4), and (1,4)(2,3).

The conjugacy classes of ${\displaystyle S_{n}}$ are in one-to-one correspondence with the partitions of the integer n. Two permutations in ${\displaystyle S_{n}}$ are conjugate in ${\displaystyle S_{n}}$ if and only the have the same lengths of cycles. These cycle lengths, including fixed points as cycles of length 1, add up to n and so form a partition of n.

Deeper Notes: Orbits and Blocks

Let ${\displaystyle G}$ be a subgroup of ${\displaystyle S_{n}}$. One may define an equivalence ${\displaystyle ~}$ relation on {1,...,n}, where ${\displaystyle i}$~${\displaystyle j}$ means that some element of ${\displaystyle G}$ maps ${\displaystyle i}$ to ${\displaystyle j}$. The resulting equivalence classes are called orbits. ${\displaystyle G}$ is called transitive if {1,...,n} forms one single orbit. Let the orbits of ${\displaystyle G}$ be ${\displaystyle O_{1},\ldots ,O_{k}}$. The action of ${\displaystyle G}$ on ${\displaystyle O_{i}}$ gives a homomorphism ${\displaystyle \phi _{i}:G\to S_{|O_{i}|}}$. While ${\displaystyle G}$ is isomorphic to a subgroup of the product of the ${\displaystyle \phi _{i}(G)}$, this product is not, in general, isomorphic to ${\displaystyle G}$. For example, any ${\displaystyle G}$ can be made to act on ${\displaystyle 2n}$ points by using two copies of its action on ${\displaystyle n}$ points. Yet no finite ${\displaystyle G}$, aside from the trivial group, is isomorphic to ${\displaystyle G\times G}$.