Optimal Bound on the Combinatorial Complexity of Approximating Polytopes

Abstract

This paper considers the question of how to succinctly approximate a multidimensional convex body by a polytope. Given a convex body K of unit diameter in Euclidean d-dimensional space (where d is a constant) and an error parameter > 0, the objective is to determine a convex polytope of low combinatorial complexity whose Hausdorff distance from K is at most . By combinatorial complexity we mean the total number of faces of all dimensions. Classical constructions by Dudley and Bronshteyn/Ivanov show that O(1/(d-1)/2) facets or vertices are possible, respectively, but neither achieves both bounds simultaneously. In this paper, we show that it is possible to construct a polytope with O(1/(d-1)/2) combinatorial complexity, which is optimal in the worst case. Our result is based on a new relationship between -width caps of a convex body and its polar body. Using this relationship, we are able to obtain a volume-sensitive bound on the number of approximating caps that are "essentially different." We achieve our main result by combining this with a variant of the witness-collector method and a novel variable-thickness layered construction of the economical cap covering.