Geometric Approach For Majorizing Measures

Abstract

Gaussian processes can be considered as subsets of a standard Hilbert space, but the geometric understanding that would relate the size of a set with the size of its convex hull is still lacking. In this work, we adopt a geometric approach to the majorizing measure problem by identifying the covering number relationships between a given space T and its convex hull, represented by Th. If the space T is a closed bounded polyhedra in Rn, we can evaluate the volume ratio between the space T and its convex hull obtained by the Quickhull algorithm. If the space T is a general compact object in Rn with non-empty interior, we first establish a more general reverse Brunn-Minkowski inequality for nonconvex spaces which will assist us to bound the volume of Th in terms of the volume of T if Th can be acquired by the finite average of the space T with respect to the Minkowski sum. If the volume ratio between the space T and the space Th is obtained, the covering number ratio between the space T and the space Th can also be obtained which will be used to build majorizing measure inequality. For infinite dimensional space, we show that the constant L at majorizing measure inequality may not always exist and the existence condition will depend on geometric properties of T.