Storing the subdivision of a polyhedral surface

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Storing the subdivision of a polyhedral surface

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Annual Symposium on Computational Geometry archive
Proceedings of the second annual symposium on Computational geometry table of contents

Yorktown Heights, New York, United States

Pages: 150 - 158

Year of Publication: 1986

ISBN:0-89791-194-6

Author

D Mount

Department of Computer Science and University of Maryland Institute for Advanced Computer Studies, University of Maryland, College Park, MD

Sponsors

SIGACT: ACM Special Interest Group on Algorithms and Computation Theory
SIGGRAPH: ACM Special Interest Group on Computer Graphics and Interactive Techniques

Publisher

ACM New York, NY, USA

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Downloads (6 Weeks): 5, Downloads (12 Months): 23, Citation Count: 2

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ABSTRACT

A common structure arising in computational geometry is the subdivision of a plane defined by the faces of a straight line planar graph. We consider a natural generalization of this structure on a polyhedral surface. The regions of the subdivision are bounded by geodesics on the surface of the polyhedron. A method is given for representing such a subdivision that is efficient both with respect to space and the time required to answer a number of different queries involving the subdivision. For example, given a point @@@@ on the surface of the polyhedron, the region of the subdivision containing x can be determined in logarithmic time. If n denotes the number of edges in the polyhedron, and m denotes the number of geodesics in the subdivision, then the space required by the data structure is &Ogr;((n + m) log (n + m)). Combined with existing algorithms for computing Voronoi diagrams on the surface of polyhedra, this structure provides an efficient solution to the nearest neighbor query problem on polyhedral surfaces.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

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	3	Herbert Edelsbrunner , Lionidas J Guibas , Jorge Stolfi, Optimal point location in a monotone subdivision, SIAM Journal on Computing, v.15 n.2, p.317-340, May 1986 [doi>10.1137/0215023]
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	8	D. M. Mount, On Finding Shortest Paths on Convex Polyhedra, Univ. of Maryland, Tech. Rept. 1495 (1985).
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CITED BY 2

	Avikam Balstan , Micha Sharir, On the shortest paths between two convex polyhedra, Journal of the ACM (JACM), v.35 n.2, p.267-287, April 1988
	Franz Aurenhammer, Voronoi diagrams—a survey of a fundamental geometric data structure, ACM Computing Surveys (CSUR), v.23 n.3, p.345-405, Sept. 1991