Expansive homeomorphism explained

In mathematics, the notion of expansivity formalizes the notion of points moving away from one another under the action of an iterated function. The idea of expansivity is fairly rigid, as the definition of positive expansivity, below, as well as the Schwarz–Ahlfors–Pick theorem demonstrate.

Definition

(X,d)

is a metric space, a homeomorphism

f\colonX\toX

is said to be expansive if there is a constant

\varepsilon_0>0,

called the expansivity constant, such that for every pair of points

x ≠ y

there is an integer

such that

d(f^n(x),f

	n(y))\geq\varepsilon

	0.

Note that in this definition,

can be positive or negative, and so

may be expansive in the forward or backward directions.

The space

is often assumed to be compact, since under that assumption expansivity is a topological property; i.e. if

is any other metric generating the same topology as

, and if

is expansive in

(X,d)

, then

is expansive in

(X,d')

(possibly with a different expansivity constant).

f\colonX\toX

is a continuous map, we say that

is positively expansive (or forward expansive) if there is a

\varepsilon₀

such that, for any

x ≠ y

, there is an

n\inN

such that

d(f^n(x),f^n(y))\geq\varepsilon₀

Theorem of uniform expansivity

Given f an expansive homeomorphism of a compact metric space, the theorem of uniform expansivity states that for every

\epsilon>0

and

\delta>0

there is an

N>0

such that for each pair

x,y

of points of

such that

d(x,y)>\epsilon

, there is an

n\inZ

with

\vertn\vert\leqN

such that

d(f^n(x),f^n(y))>c-\delta,

where

is the expansivity constant of

(proof).

Discussion

Positive expansivity is much stronger than expansivity. In fact, one can prove that if

is compact and

is a positivelyexpansive homeomorphism, then

is finite (proof).

External links

Expansive dynamical systems on scholarpedia