On longest paths and diameter in random apollonian networks
Copyright policy )On longest paths and diameter in random apollonian networks
ABSTRACTWe consider the following iterative construction of a random planar triangulation. Start with a triangle embedded in the plane. In each step, choose a bounded face uniformly at random, add a vertex inside that face and join it to the vertices of the face. After n – 3 steps, we obtain a random triangulated plane graph with n vertices, which is called a Random Apollonian Network (RAN). We show that asymptotically almost surely (a.a.s.) a longest path in a RAN has length o(n), refuting a conjecture of Frieze and Tsourakakis. We also show that a RAN always has a cycle (and thus a path) of length , and that the expected length of its longest cycles (and paths) is . Finally, we prove that a.a.s. the diameter of a RAN is asymptotic to , where is the solution of an explicit equation. © 2014 Wiley Periodicals, Inc. Random Struct. Alg., 45, 703–725, 2014
- University of Waterloo Canada
- University of Toronto Canada
- Monash University Australia
- Monash University, Clayton campus Australia
Distance in graphs, height of random trees, longest paths, Random graphs (graph-theoretic aspects), diameters of power-law graphs, random plane graphs, random Apollonian networks, Planar graphs; geometric and topological aspects of graph theory
Distance in graphs, height of random trees, longest paths, Random graphs (graph-theoretic aspects), diameters of power-law graphs, random plane graphs, random Apollonian networks, Planar graphs; geometric and topological aspects of graph theory
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