math lessons - Schwarz lemma

In mathematics, the Schwarz lemma, named after Hermann Amandus Schwarz, is a result in complex analysis about holomorphic functions defined on the open unit disk.

Let $Δ = {z : | z | < 1}$ be the open unit disk in the complex plane C. Let $f:\Delta\to\Delta$ be a holomorphic function with f(0)=0. Then

$| f(z) | \le | z |$

for all $z$ in $Δ$ , and $| f'(0) | \le 1$ . If the equality

$| f(z) |=| z |\,$

holds for any z≠0, or

$| f'(0) |=1\,$ ,

then $f$ is a rotation: $f (z) = a z$ , with $| a | = 1$ .

This lemma is less celebrated than the bigger guns (such as the Riemann mapping theorem, which it helps prove); however, it is one of the simplest results capturing the "rigidity" of holomorphic functions. No similar result exists for real functions, of course.

Schwarz-Pick theorem

A variant of the Schwarz lemma can be stated that is invariant under a change of coordinates on the unit disk. This variant is known as the Schwarz-Pick theorem:

Let $f:\Delta\to\Delta$ be holomorphic. Then, for all $z_1,z_2\in \Delta$ ,

$\left|\frac{f(z_1)-f(z_2)}{1-\overline{f(z_1)}f(z_2)}\right| \le \frac{\left|z_1-z_2\right|}{\left|1-\overline{z_1}z_2\right|}$

and, for all $z\in\Delta$

$\frac{\left|f'(z)\right|}{1-\left|f(z)\right|^2} \le \frac{1}{1-\left|z\right|^2}.$

If equality holds for either the one or the other expression, then f must be a Möbius transformation, in which case both expressions are identities.

An analogous statement on the upper half-plane $\mathbb{H}$ can be made as follows:

Let $f:\mathbb{H}\to\mathbb{H}$ be holomorphic. Then, for all $z_1,z_2\in \mathbb{H}$ ,

$\left|\frac{f(z_1)-f(z_2)}{\overline{f(z_1)}-f(z_2)}\right| \le \frac{\left|z_1-z_2\right|}{\left|\overline{z_1}-z_2\right|}$

and, for all $z\in\mathbb{H}$

$\frac{\left|f'(z)\right|}{\mbox{Im }f(z)} \le \frac{1}{\mbox{Im }(z)}.$

If equality holds for either the one or the other expression, then f must be a Möbius transformation with real coefficients, in which case both expressions are identities. That is, if equality holds, then

$f(z)=\frac{az+b}{cz+d}$

with $a, b, c, d$ being real numbers, and $a d - b c > 0$ .

Further generalizations

The Schwarz-Ahlfors-Pick theorem provides an analogous theorem for hyperbolic manifolds.

Louis De Branges' theorem is an important generalization.

References

Jurgen Jost, Compact Riemann Surfaces (2002), Springer-Verlag, New York. ISBN 3-540-43299-X (See Section 2.3)

Categories: Complex analysis | Hyperbolic geometry | Riemann surfaces | Theorems

01-04-2007 01:18:14
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Schwarz lemma

Schwarz-Pick theorem

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Mathematics Encyclopedia and Lessons

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Schwarz lemma

Schwarz-Pick theorem

Further generalizations

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