Rotation number

In mathematics, the rotation number is an invariant of homeomorphisms of the circle.

History[edit]

It was first defined by Henri Poincaré in 1885, in relation to the precession of the perihelion of a planetary orbit. Poincaré later proved a theorem characterizing the existence of periodic orbits in terms of rationality of the rotation number.

Definition[edit]

Suppose that $f:S^{1}\to S^{1}$ is an orientation-preserving homeomorphism of the circle $S^{1}=\mathbb {R} /\mathbb {Z} .$ Then $f$ may be lifted to a homeomorphism $F:\mathbb {R} \to \mathbb {R}$ of the real line, satisfying

F(x+m)=F(x)+m

for every real number $x$ and every integer $m$ .

The rotation number of $f$ is defined in terms of the iterates of $F$ :

\omega (f)=\lim _{n\to \infty }{\frac {F^{n}(x)-x}{n}}.

Henri Poincaré proved that the limit exists and is independent of the choice of the starting point $x$ . The lift $F$ is unique modulo integers, therefore the rotation number is a well-defined element of $\mathbb {R} /\mathbb {Z} .$ Intuitively, it measures the average rotation angle along the orbits of $f$ .

Example[edit]

If $f$ is a rotation by $2\pi N$ (where $0<N<1$ ), then

F(x)=x+N,

and its rotation number is $N$ (cf. irrational rotation).

Properties[edit]

The rotation number is invariant under topological conjugacy, and even monotone topological semiconjugacy: if $f$ and $g$ are two homeomorphisms of the circle and

h\circ f=g\circ h

for a monotone continuous map $h$ of the circle into itself (not necessarily homeomorphic) then $f$ and $g$ have the same rotation numbers. It was used by Poincaré and Arnaud Denjoy for topological classification of homeomorphisms of the circle. There are two distinct possibilities.

The rotation number of $f$ is a rational number $p/q$ (in the lowest terms). Then $f$ has a periodic orbit, every periodic orbit has period $q$ , and the order of the points on each such orbit coincides with the order of the points for a rotation by $p/q$ . Moreover, every forward orbit of $f$ converges to a periodic orbit. The same is true for backward orbits, corresponding to iterations of $f -1$ , but the limiting periodic orbits in forward and backward directions may be different.
The rotation number of $f$ is an irrational number $θ$ . Then $f$ has no periodic orbits (this follows immediately by considering a periodic point $x$ of $f$ ). There are two subcases.

There exists a dense orbit. In this case $f$ is topologically conjugate to the irrational rotation by the angle $θ$ and all orbits are dense. Denjoy proved that this possibility is always realized when $f$ is twice continuously differentiable.
There exists a Cantor set $C$ invariant under $f$ . Then $C$ is a unique minimal set and the orbits of all points both in forward and backward direction converge to $C$ . In this case, $f$ is semiconjugate to the irrational rotation by $θ$ , and the semiconjugating map $h$ of degree 1 is constant on components of the complement of $C$ .

The rotation number is continuous when viewed as a map from the group of homeomorphisms (with $C 0$ topology) of the circle into the circle.

References[edit]

Herman, Michael Robert (December 1979). "Sur la conjugaison différentiable des difféomorphismes du cercle à des rotations" [On the Differentiable Conjugation of Diffeomorphisms from the Circle to Rotations]. Publications Mathématiques de l'IHÉS (in French). 49: 5–233. doi:10.1007/BF02684798. S2CID 118356096., also SciSpace for smaller file size in pdf ver 1.3
Sebastian van Strien, Rotation Numbers and Poincaré's Theorem (2001)^{[permanent dead link]}

External links[edit]

Michał Misiurewicz (ed.). "Rotation theory". Scholarpedia.
Weisstein, Eric W. "Map Winding Number". From MathWorld--A Wolfram Web Resource.