Information Geometry via the Q-Root Transform
Abstract
In this paper, we introduce \emph{-information geometry}, an infinite-dimensional framework that shares key features with the geometry of the space of probability densities on a closed manifold, while also incorporating aspects of measure-valued information geometry. We define the \emph{-probability simplex} with a noncanonical differentiable structure induced via the \emph{-root transform} from an open subset of the -sphere. This choice makes the -root transform an \emph{isometry} and allows us to construct the - and -Fisher--Rao geometries, including \emph{Amari--\v{C}encov -connections} and a \emph{Chern connection} in the -setting. We then apply this framework to an infinite-dimensional linear optimization problem. We show that the corresponding gradient flow with respect to the --Fisher--Rao metric can be solved explicitly, converges to a maximizer under a natural monotonicity assumption, and admits an interpretation as the geodesic flow of an \emph{exponential connection}. In particular, we prove that this -connection is \emph{geodesically complete}. We further relate these flows to a \emph{completely integrable Hamiltonian system} through a \emph{momentum map} associated with a Hamiltonian torus action on infinite-dimensional complex projective space. Finally, inspired by the -theory, we outline an analogous Fisher--Rao geometry for on possibly noncompact Riemannian manifolds, showing that, with a suitable spherical differentiable structure, the square-root transform remains an \emph{isometry}.
Cite
@article{arxiv.2603.20081,
title = {Information Geometry via the Q-Root Transform},
author = {Levin Maier},
journal= {arXiv preprint arXiv:2603.20081},
year = {2026}
}
Comments
16 pages. Extended version of arXiv: 2506.00485