Linear Convergence in Hilbert's Projective Metric for Computing Augustin Information and a R\'enyi Information Measure

Abstract

Consider the problems of computing the Augustin information and a R\'enyi information measure of statistical independence, previously explored by Lapidoth and Pfister (IEEE Information Theory Workshop, 2018) and Tomamichel and Hayashi (IEEE Trans. Inf. Theory, 64(2):1064--1082, 2018). Both quantities are defined as solutions to optimization problems and lack closed-form expressions. This paper analyzes two iterative algorithms: Augustin's fixed-point iteration for computing the Augustin information, and the algorithm by Kamatsuka et al. (arXiv:2404.10950) for the R\'enyi information measure. Previously, it was only known that these algorithms converge asymptotically. We establish the linear convergence of Augustin's algorithm for the Augustin information of order α ∈ (1/2, 1) (1, 3/2) and Kamatsuka et al.'s algorithm for the R\'enyi information measure of order α ∈ [1/2, 1) (1, ∞), using Hilbert's projective metric.