In mathematics, and in particular in group theory, a cyclic permutation is a permutation consisting of a single cycle.[1] [2] In some cases, cyclic permutations are referred to as cycles;[3] if a cyclic permutation has k elements, it may be called a k-cycle. Some authors widen this definition to include permutations with fixed points in addition to at most one non-trivial cycle.[4] In cycle notation, cyclic permutations are denoted by the list of their elements enclosed with parentheses, in the order to which they are permuted.
For example, the permutation (1 3 2 4) that sends 1 to 3, 3 to 2, 2 to 4 and 4 to 1 is a 4-cycle, and the permutation (1 3 2)(4) that sends 1 to 3, 3 to 2, 2 to 1 and 4 to 4 is considered a 3-cycle by some authors. On the other hand, the permutation (1 3)(2 4) that sends 1 to 3, 3 to 1, 2 to 4 and 4 to 2 is not a cyclic permutation because it separately permutes the pairs and .
For the wider definition of a cyclic permutation, allowing fixed points, these fixed points each constitute trivial orbits of the permutation, and there is a single non-trivial orbit containing all the remaining points. This can be used as a definition: a cyclic permutation (allowing fixed points) is a permutation that has a single non-trivial orbit. Every permutation on finitely many elements can be decomposed into cyclic permutations whose non-trivial orbits are disjoint.[5]
The individual cyclic parts of a permutation are also called cycles, thus the second example is composed of a 3-cycle and a 1-cycle (or fixed point) and the third is composed of two 2-cycles.
A cyclic permutation consisting of a single 8-cycle.|thumb
There is not widespread consensus about the precise definition of a cyclic permutation. Some authors define a permutation of a set to be cyclic if "successive application would take each object of the permuted set successively through the positions of all the other objects", or, equivalently, if its representation in cycle notation consists of a single cycle. Others provide a more permissive definition which allows fixed points.
A nonempty subset of is a cycle of
\sigma
\sigma
\sigma.
For example, the permutation, written in cycle notation and two-line notation (in two ways) as
\begin{align} (1 4 6 &8 3 7)(2)(5)\\ &= \begin{pmatrix}1&2&3&4&5&6&7&8\ 4&2&7&6&5&8&1&3\end{pmatrix}\\ &= \begin{pmatrix}1&4&6&8&3&7&2&5\ 4&6&8&3&7&1&2&5\end{pmatrix}\end{align}
thumb|A permutation that is cyclic for the enlarged definition but not for the restricted one, with two fixed points (1-cycles) and a 6-cycleWith the enlarged definition, there are cyclic permutations that do not consist of a single cycle.
More formally, for the enlarged definition, a permutation
\sigma
\sigma:X\toX
\sigma
s0
| i(s | |
| s | |
| 0) |
i\inZ
k\geq1
sk=s0
S=\{s0,s1,\ldots,sk-1\}
\sigma
\sigma(si)=si+1
and
\sigma(x)=x
X\setminusS
\sigma
s0\mapstos1\mapstos2\mapsto … \mapstosk-1\mapstosk=s0
\sigma=(s0~s1~...~sk-1)
The orbit of a 1-cycle is called a fixed point of the permutation, but as a permutation every 1-cycle is the identity permutation. When cycle notation is used, the 1-cycles are often omitted when no confusion will result.
One of the basic results on symmetric groups is that any permutation can be expressed as the product of disjoint cycles (more precisely: cycles with disjoint orbits); such cycles commute with each other, and the expression of the permutation is unique up to the order of the cycles. The multiset of lengths of the cycles in this expression (the cycle type) is therefore uniquely determined by the permutation, and both the signature and the conjugacy class of the permutation in the symmetric group are determined by it.
The number of k-cycles in the symmetric group Sn is given, for
1\leqk\leqn
A k-cycle has signature (−1)k − 1.
The inverse of a cycle
\sigma=(s0~s1~...~sk-1)
\sigma-1=(sk~...~s1~s0)
(a~b)=(b~a)
A cycle with only two elements is called a transposition. For example, the permutation
\pi=\begin{pmatrix}1&2&3&4\ 1&4&3&2\end{pmatrix}
\pi=(2,4)
Any permutation can be expressed as the composition (product) of transpositions—formally, they are generators for the group. In fact, when the set being permuted is for some integer, then any permutation can be expressed as a product of
(1~2),(2~3),(3~4),
(k~~l)
k<l
(k~~l)=(k~~k+1) ⋅ (k+1~~k+2) … (l-1~~l) ⋅ (l-2~~l-1) … (k~~k+1).
The decomposition of a permutation into a product of transpositions is obtained for example by writing the permutation as a product of disjoint cycles, and then splitting iteratively each of the cycles of length 3 and longer into a product of a transposition and a cycle of length one less:
(a~b~c~d~\ldots~y~z)=(a~b) ⋅ (b~c~d~\ldots~y~z).
This means the initial request is to move
a
b,
b
c,
y
z,
z
a.
a
z
b,
a
z
(a~b),
z
b
a
z.
In fact, the symmetric group is a Coxeter group, meaning that it is generated by elements of order 2 (the adjacent transpositions), and all relations are of a certain form.
One of the main results on symmetric groups states that either all of the decompositions of a given permutation into transpositions have an even number of transpositions, or they all have an odd number of transpositions. This permits the parity of a permutation to be a well-defined concept.