Structure theorems for Power Series in Several Complex Variables
Abstract
It is a classical fact that domains of convergence of power series of several complex variables are characterized as logarithmically convex complete Reinhardt domains; let be such a domain. We show that a necessary as well as sufficient condition for a power series to have as its domain of convergence is that it admits a certain decomposition into elementary power series; specifically, can be expressed as a sum of a sequence of power series with the property that each of the logarithmic images of their domains of convergence are half-spaces, all containing the logarithmic image of and such that the largest open subset of on which all the 's and converge absolutely is . In short, every power series admits a decomposition into elementary power series. The proof of this leads to a new way of arriving at a constructive proof of the aforementioned classical fact. This proof inturn leads to another decomposition result in which the 's are now wedges formed by intersections of pairs of {\it supporting} half-spaces of . Along the way, we also show that in each fiber of the restriction of the absolute map to the boundary of the domain of convergence of , there exists a singular point of .
Cite
@article{arxiv.2103.13986,
title = {Structure theorems for Power Series in Several Complex Variables},
author = {G. P. Balakumar},
journal= {arXiv preprint arXiv:2103.13986},
year = {2021}
}
Comments
This version makes a considerable improvement in the exposition and sets right some errors which could have been rather confusing in the first version; the main changes (which are particularly in the introductory section), are highlighted in blue and red colors. The proofs of all theorems remain the same