Packing d-dimensional balls into a d+1-dimensional container
Abstract
In this article, we consider the problems of finding in d+1 dimensions a minimum-volume axis-parallel box, a minimum-volume arbitrarily-oriented box and a minimum-volume convex body into which a given set of d-dimensional unit-radius balls can be packed under translations. The computational problem is neither known to be NP-hard nor to be in NP. We give a constant-factor approximation algorithm for each of these containers based on a reduction to finding a shortest Hamiltonian path in a weighted graph, which in turn models the problem of stabbing the centers of the input balls while keeping them disjoint. We also show that for n such balls, a container of volume O(nd-1d) is always sufficient and sometimes necessary. As a byproduct, this implies that for d ≥ 2 there is no finite size (d+1)-dimensional convex body into which all d-dimensional unit-radius balls can be packed simultaneously.
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