Random Modulation with Spherical Symmetry
Abstract
We consider the modulation of data given by random vectors , . For each , one chooses an independent modulating random vector and forms the projection . It is shown, under regularity conditions on and , that converges weakly in probability to a normal distribution. More broadly, the conditional joint distribution of a family of projections constructed from random samples from and is shown to converge weakly to a matrix normal distribution. We derive, \textit{via} G. P\'olya's characterization of the normal distribution, a necessary and sufficient condition on for to be normally distributed. When has a spherically symmetric distribution we deduce, through I. J. Schoenberg's characterization of the spherically symmetric characteristic functions on Hilbert spaces, that the probability density function of converges pointwise in certain th means to a mixture of normal densities and the rate of convergence is quantified, resulting in uniform convergence. The cumulative distribution function of is shown to converge uniformly in those th means to the distribution function of the same mixture, and a Lipschitz property is obtained. Examples of distributions satisfying our results are provided; these include Bingham distributions on hyperspheres of random radii, uniform distributions on hyperspheres and hypercubes of random volumes, and multivariate normal distributions; and examples of such include the multivariate -, multivariate Laplace, and spherically symmetric stable distributions.
Cite
@article{arxiv.2510.12928,
title = {Random Modulation with Spherical Symmetry},
author = {Armine Bagyan and Donald Richards},
journal= {arXiv preprint arXiv:2510.12928},
year = {2025}
}
Comments
44 pages