Exponential integral representations of theta functions

Abstract

Let 3 (z):= Σn∈Z (i π n2 z) be the standard Jacobi theta function, which is holomorphic and zero-free in the upper half-plane H, and takes positive values along the positive imaginary axis. We define its logarithm 3(z) which is uniquely determined by the requirements that it should be holomorphic in H and real-valued on the positive imaginary axis. We derive an integral representation of 3 (z) when z belongs to the hyperbolic quadrilateral F||, consisted of all those z ∈ H which satisfy -1 ≤ Re\, z ≤ 1, |2 z - 1| > 1 and |2 z + 1| > 1. Since every point of H is equivalent to at least one point in F|| under the theta subgroup of the modular group on the upper half-plane, this representation carries over in modified form to all of H via the identity recorded by Berndt. The logarithms of the related Jacobi theta functions 4 and 2 may be conveniently expressed in terms of 3 via functional equations, and hence get controlled as well. Our approach is based on a study the logarithm of the Gauss hypergeometric function for a specific choice of the parameters. This connects with the study of the universally starlike mappings introduced by Ruscheweyh, Salinas, and Sugawa.