English

Arithmetic progressions and holomorphic phase retrieval

Complex Variables 2025-05-06 v2 Functional Analysis

Abstract

We study the determination of a holomorphic function from its absolute value. Given a parameter θR\theta \in \mathbb{R}, we derive the following characterization of uniqueness in terms of rigidity of a set ΛR\Lambda \subseteq \mathbb{R}: if F\mathcal{F} is a vector space of entire functions containing all exponentials eξz,ξC{0}e^{\xi z}, \, \xi \in \mathbb{C} \setminus \{ 0 \}, then every FFF \in \mathcal{F} is uniquely determined up to a unimodular phase factor by {F(z):zeiθ(R+iΛ)}\{|F(z)| : z \in e^{i\theta}(\mathbb{R} + i\Lambda)\} if and only if Λ\Lambda is not contained in an arithmetic progression aZ+ba\mathbb{Z}+b. Leveraging this insight, we establish a series of consequences for Gabor phase retrieval and Pauli-type uniqueness problems. For instance, Z×Z~\mathbb{Z} \times \tilde{\mathbb{Z}} is a uniqueness set for the Gabor phase retrieval problem in L2(R+)L^2(\mathbb{R}_+), provided that Z~\tilde{\mathbb{Z}} is a suitable perturbation of the integers.

Keywords

Cite

@article{arxiv.2308.05722,
  title  = {Arithmetic progressions and holomorphic phase retrieval},
  author = {Lukas Liehr},
  journal= {arXiv preprint arXiv:2308.05722},
  year   = {2025}
}

Comments

14 pages

R2 v1 2026-06-28T11:53:02.421Z