Approximating Densest Subgraph in Geometric Intersection Graphs

Abstract

[1]| #1 |% G% % % H% H% V% [1]#1% E% E% R R X r [1]#1 q [1]V #1 P [1][ #1 ] m [2][\!]#1(#2) polylog N Z p [2]\| #1 - #2 \| q s For an undirected graph G=(V, E), with n vertices and m edges, the densest subgraph problem, is to compute a subset S ⊂eq V which maximizes the ratio |ES| / |S|, where ES ⊂eq E is the set of all edges of G with endpoints in S. The densest subgraph problem is a well studied problem in computer science. Existing exact and approximation algorithms for computing the densest subgraph require (m) time. We present near-linear time (in n) approximation algorithms for the densest subgraph problem on implicit geometric intersection graphs, where the vertices are explicitly given but not the edges. As a concrete example, we consider n disks in the plane with arbitrary radii and present two different approximation algorithms.

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