Shallow Packings in Geometry

Abstract

We refine the bound on the packing number, originally shown by Haussler, for shallow geometric set systems. Specifically, let be a finite set system defined over an n-point set X; we view as a set of indicator vectors over the n-dimensional unit cube. A δ-separated set of is a subcollection , s.t. the Hamming distance between each pair , ∈ is greater than δ, where δ > 0 is an integer parameter. The δ-packing number is then defined as the cardinality of the largest δ-separated subcollection of . Haussler showed an asymptotically tight bound of ((n/δ)d) on the δ-packing number if has VC-dimension (or primal shatter dimension) d. We refine this bound for the scenario where, for any subset, X' ⊂eq X of size m n and for any parameter 1 k m, the number of vectors of length at most k in the restriction of to X' is only O(md1 kd-d1), for a fixed integer d > 0 and a real parameter 1 d1 d (this generalizes the standard notion of bounded primal shatter dimension when d1 = d). In this case when is "k-shallow" (all vector lengths are at most k), we show that its δ-packing number is O(nd1 kd-d1/δd), matching Haussler's bound for the special cases where d1=d or k=n. As an immediate consequence we conclude that set systems of halfspaces, balls, and parallel slabs defined over n points in d-space admit better packing numbers when k is smaller than n. Last but not least, we describe applications to (i) spanning trees of low total crossing number, and (ii) geometric discrepancy, based on previous work by the author.