English

Valence of complex-valued planar harmonic functions

Complex Variables 2007-05-23 v1 Geometric Topology

Abstract

The valence of a function ff at a point ww is the number of distinct, finite solutions to f(z)=wf(z) = w. Let ff be a complex-valued harmonic function in an open set RCR \subseteq \mathbb{C}. Let SS denote the critical set of ff and C(f)C(f) the global cluster set of ff. We show that f(S)C(f)f(S) \cup C(f) partitions the complex plane into regions of constant valence. We give some conditions such that f(S)C(f)f(S) \cup C(f) has empty interior. We also show that a component R0R\f1(f(S)C(f))R_0 \subseteq R \backslash f^{-1}(f(S) \cup C(f)) is a n0n_0-fold covering of some component Ω0C\(f(S)C(f))\Omega_0 \subseteq \mathbb{C} \backslash (f(S) \cup C(f)). If Ω0\Omega_0 is simply connected, then ff is univalent on R0R_0. We explore conditions for combining adjacent components to form a larger region of univalence. Those results which hold for C1C^1 functions on open sets in R2\mathbb{R}^2 are first stated in that form and then applied to the case of planar harmonic functions. If ff is a light, harmonic function in the complex plane, we apply a structure theorem of Lyzzaik to gain information about the difference in valence between components of C\(f(S)C(f))\mathbb{C} \backslash (f(S) \cup C(f)) sharing a common boundary arc in f(S)\C(f)f(S) \backslash C(f).

Keywords

Cite

@article{arxiv.math/0401359,
  title  = {Valence of complex-valued planar harmonic functions},
  author = {Genevra Neumann},
  journal= {arXiv preprint arXiv:math/0401359},
  year   = {2007}
}

Comments

31 pages, 10 figures. Question for geometers: Please email the author if you know of results similar to Theorem 3.4 in this paper