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| Title of object: |
Reinhardt domain |
| Canonical Name: |
ReinhardtDomain |
| Type: |
Definition |
| Created on: |
2004-07-26 13:02:31 |
| Modified on: |
2004-07-26 13:02:31 |
| Classification: |
msc:32A07 |
Revision comment (for changes between this and next version):
| moved thm stuff to preamble |
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Content:
\theoremstyle{definition}
\newtheorem*{defn}{Definition}
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\newtheorem*{thm}{Theorem}
\begin{defn}
We call an open set $G \subset {\mathbb{C}}^n$ a {\em Reinhardt domain}
if $(z_1,\ldots,z_n) \in G$ implies that
$(e^{i\theta_1}z_1,\ldots,e^{i\theta_n}z_n) \in G$ for all real
$\theta_1,\ldots,\theta_n$.
\end{defn}
The reason for studying these kinds of domains is that
\PMlinkname{logarithmically convex}{LogarithmicallyConvexSet}
Reinhardt domain are the domains of convergence of power series in
several complex variables. Note that in one complex variable, a
\PMlinkescapetext{logarithmically convex}
Reinhardt domain is just a disc.
Note that the intersection of
\PMlinkescapetext{logarithmically convex}
Reinhardt domains is still a
\PMlinkescapetext{logarithmically convex}
Reinhardt domain, so for every Rienhardt domain, there is a smallest
\PMlinkescapetext{logarithmically convex}
Reinhardt domain which contains it.
\begin{thm}
Suppose that $G$ is a Reinhardt domain which contains 0.
then suppose that $\tilde{G}$ is the smallest
\PMlinkescapetext{logarithmically convex}
Reinhardt domain such that $G \subset \tilde{G}$. Then
any function holomorphic on $G$ has a holomorphic \PMlinkescapetext{extension}
to $\tilde{G}$.
\end{thm}
It actually turns out that a
\PMlinkescapetext{logarithmically convex}
Reinhardt domain is a domain of convergence.
\PMlinkescapetext{Simple} examples of
\PMlinkescapetext{logarithmically convex}
Reinhardt domains in ${\mathbb{C}}^n$ are polydiscs such as
$\underbrace{{\mathbb{D}} \times \ldots \times {\mathbb{D}}}_n$
where ${\mathbb{D}} \subset {\mathbb{C}}$ is the unit disc.
\begin{thebibliography}{9}
\bibitem{Hormander:several}
Lars H\"ormander.
{\em \PMlinkescapetext{An Introduction to Complex Analysis in Several
Variables}},
North-Holland Publishing Company, New York, New York, 1973.
\bibitem{Krantz:several}
Steven~G.\@ Krantz.
{\em \PMlinkescapetext{Function Theory of Several Complex Variables}},
AMS Chelsea Publishing, Providence, Rhode Island, 1992.
\end{thebibliography} |
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