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Link to original content: https://doi.org/10.46298/dmtcs.2126
#2126 - A randomized algorithm for finding a maximum clique in the visibility graph of a simple polygon

Sergio Cabello ; Maria Saumell - A randomized algorithm for finding a maximum clique in the visibility graph of a simple polygon

dmtcs:2126 - Discrete Mathematics & Theoretical Computer Science, January 21, 2015, Vol. 17 no. 1 - https://doi.org/10.46298/dmtcs.2126
A randomized algorithm for finding a maximum clique in the visibility graph of a simple polygonArticle

Authors: Sergio Cabello ORCID1; Maria Saumell ORCID1,2

  • 1 Department of Mathematics
  • 2 European Centre of Excellence NTIS

We present a randomized algorithm to compute a clique of maximum size in the visibility graph G of the vertices of a simple polygon P. The input of the problem consists of the visibility graph G, a Hamiltonian cycle describing the boundary of P, and a parameter δ∈(0,1) controlling the probability of error of the algorithm. The algorithm does not require the coordinates of the vertices of P. With probability at least 1-δ the algorithm runs in O( |E(G)|2 / ω(G) log(1/δ)) time and returns a maximum clique, where ω(G) is the number of vertices in a maximum clique in G. A deterministic variant of the algorithm takes O(|E(G)|2) time and always outputs a maximum size clique. This compares well to the best previous algorithm by Ghosh et al. (2007) for the problem, which is deterministic and runs in O(|V(G)|2 |E(G)|) time.


Volume: Vol. 17 no. 1
Section: Discrete Algorithms
Published on: January 21, 2015
Submitted on: October 18, 2013
Keywords: randomized algorithm,visibility graph,maximum clique,simple polygon,[INFO.INFO-DM] Computer Science [cs]/Discrete Mathematics [cs.DM],[INFO.INFO-HC] Computer Science [cs]/Human-Computer Interaction [cs.HC]

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