mathematics Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented in modern mathematics ...

, the Earle–Hamilton fixed point theorem is a result in

geometric function theory Geometric function theory is the study of geometric properties of analytic functions. A fundamental result in the theory is the Riemann mapping theorem. Topics in geometric function theory The following are some of the most important topics in ge ...

giving sufficient conditions for a

holomorphic mapping In differential geometry and complex geometry, a complex manifold is a manifold with an atlas of charts to the open unit disc in \mathbb^n, such that the transition maps are holomorphic. The term complex manifold is variously used to mean a c ...

of an open domain in a complex

Banach space In mathematics, more specifically in functional analysis, a Banach space (pronounced ) is a complete normed vector space. Thus, a Banach space is a vector space with a metric that allows the computation of vector length and distance between vector ...

into itself to have a fixed point. The result was proved in 1968 by Clifford Earle and Richard S. Hamilton by showing that, with respect to the

Carathéodory metric In mathematics, the Carathéodory metric is a metric defined on the open unit ball of a complex Banach space that has many similar properties to the Poincaré metric of hyperbolic geometry. It is named after the Greek mathematician Constantin Cara ...

on the domain, the holomorphic mapping becomes a

contraction mapping In mathematics, a contraction mapping, or contraction or contractor, on a metric space (''M'', ''d'') is a function ''f'' from ''M'' to itself, with the property that there is some real number 0 \leq k < 1 such that for all ''x'' and ...

to which the

Banach fixed-point theorem In mathematics, the Banach fixed-point theorem (also known as the contraction mapping theorem or contractive mapping theorem) is an important tool in the theory of metric spaces; it guarantees the existence and uniqueness of fixed points of certai ...

can be applied.

Statement

Let ''D'' be a connected open subset of a complex

''X'' and let ''f'' be a holomorphic mapping of ''D'' into itself such that: *the image ''f''(''D'') is bounded in norm; *the distance between points ''f''(''D'') and points in the exterior of ''D'' is bounded below by a positive constant. Then the mapping ''f'' has a unique fixed point ''x'' in ''D'' and if ''y'' is any point in ''D'', the iterates ''f''^''n''(''y'') converge to ''x''.

Proof

Replacing ''D'' by an ε-neighbourhood of ''f''(''D''), it can be assumed that ''D'' is itself bounded in norm. For ''z'' in ''D'' and ''v'' in ''X'', set :

\displaystyle

where the supremum is taken over all holomorphic functions ''g'' on ''D'' with , ''g''(''z''), < 1. Define the α-length of a piecewise differentiable curve γ: ,1

\rightarrow

''D'' by :

\displaystyle

The Carathéodory metric is defined by :

\displaystyle

for ''x'' and ''y'' in ''D''. It is a continuous function on ''D'' x ''D'' for the norm topology. If the diameter of ''D'' is less than ''R'' then, by taking suitable holomorphic functions ''g'' of the form :

\displaystyle

with ''a'' in ''X''* and ''b'' in C, it follows that :

\displaystyle

and hence that :

\displaystyle

In particular ''d'' defines a metric on ''D''. The chain rule :

\displaystyle

implies that :

\displaystyle

and hence ''f'' satisfies the following generalization of the Schwarz-Pick inequality: :

\displaystyle

For δ sufficiently small and ''y'' fixed in ''D'', the same inequality can be applied to the holomorphic mapping :

\displaystyle

and yields the improved estimate: :

\displaystyle

The Banach fixed-point theorem can be applied to the restriction of ''f'' to the closure of ''f''(''D'') on which ''d'' defines a complete metric, defining the same topology as the norm.

Other holomorphic fixed point theorems

In finite dimensions the existence of a fixed point can often be deduced from the

Brouwer fixed point theorem Brouwer's fixed-point theorem is a fixed-point theorem in topology, named after L. E. J. (Bertus) Brouwer. It states that for any continuous function f mapping a compact convex set to itself there is a point x_0 such that f(x_0)=x_0. The simplest ...

without any appeal to holomorphicity of the mapping. In the case of

bounded symmetric domain In mathematics, a Hermitian symmetric space is a Hermitian manifold which at every point has an inversion symmetry preserving the Hermitian structure. First studied by Élie Cartan, they form a natural generalization of the notion of Riemannian s ...

s with the

Bergman metric In differential geometry, the Bergman metric is a Hermitian metric that can be defined on certain types of complex manifold. It is so called because it is derived from the Bergman kernel, both of which are named after Stefan Bergman. Definition ...

, and showed that the same scheme of proof as that used in the Earle-Hamilton theorem applies. The bounded symmetric domain ''D'' = ''G'' / ''K'' is a complete metric space for the Bergman metric. The open semigroup of the complexification ''G''_''c'' taking the closure of ''D'' into ''D'' acts by

s, so again the Banach fixed-point theorem can be applied. Neretin extended this argument by continuity to some infinite-dimensional bounded symmetric domains, in particular the Siegel generalized disk of symmetric Hilbert-Schmidt operators with operator norm less than 1. The Earle-Hamilton theorem applies equally well in this case.

References

* * * * {{DEFAULTSORT:Earle-Hamilton fixed-point theorem Theorems in complex analysis Fixed-point theorems