Functional John Ellipsoids
Abstract
We introduce a new way of representing logarithmically concave functions on . It allows us to extend the notion of the largest volume ellipsoid contained in a convex body to the setting of logarithmically concave functions as follows. For every , we define a class of non-negative functions on derived from ellipsoids in . For any log-concave function on , and any fixed , we consider functions belonging to this class, and find the one with the largest integral under the condition that it is pointwise less than or equal to , and we call it the \emph{\jsfunction} of . After establishing existence and uniqueness, we give a characterization of this function similar to the one given by John in his fundamental theorem. We find that John -functions converge to characteristic functions of ellipsoids as tends to zero and to Gaussian densities as tends to infinity. As an application, we prove a quantitative Helly type result: the integral of the pointwise minimum of any family of log-concave functions is at least a constant multiple of the integral of the pointwise minimum of a properly chosen subfamily of size , where depends only on .
Cite
@article{arxiv.2006.09934,
title = {Functional John Ellipsoids},
author = {Grigory Ivanov and Márton Naszódi},
journal= {arXiv preprint arXiv:2006.09934},
year = {2021}
}
Comments
Clean version