Quasisymmetric map

In mathematics, a quasisymmetric homeomorphism between metric spaces is a map that generalizes bi-Lipschitz maps. While bi-Lipschitz maps shrink or expand the diameter of a set by no more than a multiplicative factor, quasisymmetric maps satisfy the weaker geometric property that they preserve the relative sizes of sets: if two sets A and B have diameters t and are no more than distance t apart, then the ratio of their sizes changes by no more than a multiplicative constant. These maps are also related to quasiconformal maps, since in many circumstances they are in fact equivalent^[1].

Let (X,d_X) and (Y,d_Y) be two metric spaces. A homeomorphism f:X→Y is said to be η-quasisymmetric or if there is an increasing function η:[0,∞)→[0,∞) such that for any triple x,y,z of distinct points in X, we have

${\displaystyle {\frac {d_{Y}(f(x),f(y))}{d_{Y}(f(x),f(z))}}\leq \eta \left({\frac {|x-y|}{|x-z|}}\right).}$

Inverses are quasisymmetric

If f:X→Y is an invertible η-quasisymmetric map as above, then its inverse map is ή-quasisymmetric, where ή(t)=1/η(1/t).

Quasisymmetric maps preserve relative sizes of sets

If A and B are subsets of X and A is a subset of B, then

${\displaystyle {\frac {1}{2\eta ({\frac {{\mbox{diam }}B}{{\mbox{diam }}A}})}}\leq {\frac {{\mbox{diam }}f(B)}{{\mbox{diam }}f(A)}}\leq \eta ({\frac {{\mbox{diam }}B}{{\mbox{diam }}A}}).}$

A map f:X→Y is said to be H-weakly-quasisymmetric for some H>0 if for all triples of distinct points x,y,z in X, we have

${\displaystyle |f(x)-f(y)|\leq H|f(x)-f(z)|\;\;\;{\mbox{ whenever }}\;\;\;|x-y|\leq |x-z|}$

Not all weakly-quasisymmetric maps are quasisymmetric. However, if X is connected and doubling, then all weakly-quasisymmetric maps are quasisymmetric. The appeal of this result is that proving weak-quasisymmetry is much easier than proving quasisymmetry directly, and in many natural settings we have the luck of knowing the two are equivalent.

A monotone map f:H→H on a Hilbert space H is δ-monotone if for all x and y in H,

${\displaystyle \langle f(x)-f(y),x-y\rangle \geq \delta |f(x)-f(y)|\cdot |x-y|.}$

To grasp what this condition means geometrically, suppose f(0)=0 and consider the above estimate when y=0. Then it implies that the angle between the vector x and its image f(x) stays between 0 and arccosδ<π/2.

These maps are quasisymmetric, although they are a much narrower subclass of quasisymmetric maps. For example, while a general quasisymmetric map in the complex plane could map the real line to a set of Hausdorff dimension strictly greater than one, a δ-monotone will always map the real line to a rotated graph of a Lipschitz function L:ℝ→ℝ^[2].

Quasisymmetric homeomorphisms of the real line to itself can be characterized in terms of their derivatives^[3]. An increasing homeomorphism f:ℝ→ℝ is quasisymmetric if and only if there is a constant C>0 and a doubling measure μ on the real line such that

${\displaystyle f(x)=C+\int _{0}^{x}d\mu (t).}$

An analogous result holds in Euclidean space. Suppose C=0 and we rewrite the above equation for f as

${\displaystyle f(x)={\frac {1}{2}}\int _{\mathbb {R} }\left({\frac {x-t}{|x-t|}}+{\frac {t}{|t|}}\right)d\mu (t).}$

Writing it this way, we can attempt to define a map using this same integral, but instead integrate (what is now a vector valued integrand) over ℝⁿ: if μ is a doubling measure on ℝⁿ and

${\displaystyle \int _{|x|>1}{\frac {1}{|x|}}d\mu (x)<\infty }$

then the map

${\displaystyle f(x)={\frac {1}{2}}\int _{\mathbb {R} ^{n}}\left({\frac {x-y}{|x-y|}}+{\frac {y}{|y|}}\right)d\mu (y)}$

is quasisymmetric (in fact, it is δ-monotone for some δ depending on the measure μ)^[4].

Let Ω and Ω´ be open subsets of ℝⁿ. If f:Ω→Ω´ is η-quasisymmetric, then it is also K-quasiconformal, where K>0 is a constant depending on η.

Conversely, if f:Ω→Ω´ is K-quasiconformal and B(x,2r) is contained in Ω, then f is η-quasisymmetric on B(x,r), where η depends only on K.