TY - GEN
T1 - Balancing graph Voronoi diagrams
AU - Honide, Shinichi
AU - Houle, Michael E.
AU - Sommer, Christian
PY - 2009/12/1
Y1 - 2009/12/1
N2 - Many facility location problems are concerned with minimizing operation and transportation costs by partitioning territory into regions of similar size, each of which is served by a facility. For many optimization problems, the overall cost can be reduced by means of a partitioning into balanced subsets, especially in those cases where the cost associated with a subset is superlinear in its size. In this paper, we consider the problem of generating a Voronoi partition of a discrete graph so as to achieve balance conditions on the region sizes. Through experimentation, we first establish that the region sizes of randomly-generated graph Voronoi diagrams vary greatly in practice.We then show how to achieve a balanced partition of a graph via Voronoi site resampling. For bounded-degree graphs, where each of the n nodes has degree at most d, and for an initial randomly-chosen set of s Voronoi nodes, we prove that, by extending the set of Voronoi nodes using an algorithm by Thorup and Zwick, each Voronoi region has size at most 4dn/s+1 nodes, and that the expected size of the extended set of Voronoi nodes is at most 2s log n.
AB - Many facility location problems are concerned with minimizing operation and transportation costs by partitioning territory into regions of similar size, each of which is served by a facility. For many optimization problems, the overall cost can be reduced by means of a partitioning into balanced subsets, especially in those cases where the cost associated with a subset is superlinear in its size. In this paper, we consider the problem of generating a Voronoi partition of a discrete graph so as to achieve balance conditions on the region sizes. Through experimentation, we first establish that the region sizes of randomly-generated graph Voronoi diagrams vary greatly in practice.We then show how to achieve a balanced partition of a graph via Voronoi site resampling. For bounded-degree graphs, where each of the n nodes has degree at most d, and for an initial randomly-chosen set of s Voronoi nodes, we prove that, by extending the set of Voronoi nodes using an algorithm by Thorup and Zwick, each Voronoi region has size at most 4dn/s+1 nodes, and that the expected size of the extended set of Voronoi nodes is at most 2s log n.
KW - Balancing
KW - Facility location
KW - Graph Voronoi diagram
KW - Territorial design
UR - http://www.scopus.com/inward/record.url?scp=77951472302&partnerID=8YFLogxK
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U2 - 10.1109/ISVD.2009.26
DO - 10.1109/ISVD.2009.26
M3 - Conference contribution
AN - SCOPUS:77951472302
SN - 9780769537818
T3 - 6th International Symposium on Voronoi Diagrams in Science and Engineering, ISVD 2009
SP - 183
EP - 191
BT - 6th International Symposium on Voronoi Diagrams in Science and Engineering, ISVD 2009
T2 - 6th International Symposium on Voronoi Diagrams in Science and Engineering, ISVD 2009
Y2 - 23 June 2009 through 26 June 2009
ER -