Determining the maximum clique size in large random geometric graphs

Author

Derici, Ilteris Murat ; Panu, Mihai Tudor

Author_Institution

Comput. Sci. & Eng. Dept., Southern Methodist Univ., Dallas, TX, USA

fYear

2011

fDate

4-8 July 2011

Firstpage

143

Lastpage

154

Abstract

For a geometric graph on a topology, we employ an iterated version of the smallest last coloring algorithm to obtain either the largest clique or very tight bounds on its size. The procedure is topology independent and runs in two phases, global and local. We exploit pruning methods in building the geometric graphs and in limiting the number of sub-graphs searched. We have performed experiments using random geometric graphs in the plane and on the sphere, and provide computational results. The time complexity of the algorithm is O(|E| ×|V| + |V|²) where |E| and |V| are the cardinalities of a geometric graph´s edge set and vertex set, respectively.

Keywords

computational complexity; graph colouring; set theory; graph edge set; graph topology; graph vertex set; maximum clique size determination; random geometric graph; smallest last coloring algorithm; time complexity; Color; Noise; Pipelines; Radiation detectors; Random access memory; Topology; Cliques; Large Scale Scientific Computing; Scheduling; Sensor Networks; Unit Disk Graphs; Wireless Applications;

fLanguage

English

Publisher

ieee

Conference_Titel

High Performance Computing and Simulation (HPCS), 2011 International Conference on

Conference_Location

Istanbul

Print_ISBN

978-1-61284-380-3

Type

conf

DOI

10.1109/HPCSim.2011.5999818

Filename

5999818