On the Diameter of Arrangements of Topological Disks

Abstract

Let D=\D0,…,Dn-1\ be a set of n topological disks in the plane and let A := A(D) be the arrangement induced by D. For two disks Di,Dj∈D, let ij be the number of connected components of Di Dj, and let := i,j ij. We show that the diameter of G*, the dual graph of A, can be bounded as a function of n and . Thus, any two points in the plane can be connected by a Jordan curve that crosses the disk boundaries a number of times bounded by a function of n and . In particular, for the case of two disks, we prove that the diameter of G* is at most \2,2\ and this bound is tight. For the general case of n>2 disks, we show that the diameter of G* is O(n3 2n ). We achieve this by proving that the number of maximal faces in A -- faces whose ply is more than the ply of their neighboring faces -- is O(n2 2n ). To this end, we first show that the number of maximum faces -- faces whose ply is n -- is O(n2); the latter bound, which is of independent interest, is tight in the worst case.

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