Calculating approximate curve arrangements using rounded arithmetic

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Calculating approximate curve arrangements using rounded arithmetic

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

Saarbruchen, West Germany

Pages: 197 - 207

Year of Publication: 1989

ISBN:0-89791-318-3

Author

V. Milenkovic

Harvard University

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): 3, Downloads (12 Months): 13, Citation Count: 9

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ABSTRACT

We present here an algorithm for the curve arrangement problem: determine how a set of planar curves subdivides the plane. This algorithm uses rounded arithmetic and generates an approximate result. It can be applied to a broad class of planar curves, and it is based on a new definition of approximate curve arrangements. This result is an important step towards the creation of practical computer programs for reasoning about algebraic curves of high degree.

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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CITED BY 9

	Mark Segal, Using tolerances to guarantee valid polyhedral modeling results, ACM SIGGRAPH Computer Graphics, v.24 n.4, p.105-114, Aug. 1990
	Pankaj K. Agarwal , Subhash Suri, Simple and practical geometric algorithms, ACM Computing Surveys (CSUR), v.28 n.4es, Dec. 1996
	Simon Kahan , Jack Snoeyink, On the bit complexity of minimum link paths: superquadratic algorithms for problems solvable in linear time, Proceedings of the twelfth annual symposium on Computational geometry, p.151-158, May 24-26, 1996, Philadelphia, Pennsylvania, United States
	Yossi Matias , Jeffrey Scott Vitter , Neal E. Young, Approximate data structures with applications, Proceedings of the fifth annual ACM-SIAM symposium on Discrete algorithms, p.187-194, January 23-25, 1994, Arlington, Virginia, United States
	Zhenyu Li , Victor Milenkovic, Constructing strongly convex hulls using exact or rounded arithmetic, Proceedings of the sixth annual symposium on Computational geometry, p.235-243, June 07-09, 1990, Berkley, California, United States
	Wei Chen , Koichi Wada , Kimio Kawaguchi, Parallel robust algorithms for constructing strongly convex hulls, Proceedings of the twelfth annual symposium on Computational geometry, p.133-140, May 24-26, 1996, Philadelphia, Pennsylvania, United States
	Michael Karasick , Derek Lieber , Lee R. Nackman, Efficient Delaunay triangulation using rational arithmetic, ACM Transactions on Graphics (TOG), v.10 n.1, p.71-91, Jan. 1991
	Wei Chen , Koichi Wada , Kimio Kawaguchi, Robust algorithms for constructing strongly convex hulls in parallel, Theoretical Computer Science, v.289 n.1, p.277-295, 23 October 2002
	L. Alberti , B. Mourrain , J. Wintz, Topology and arrangement computation of semi-algebraic planar curves, Computer Aided Geometric Design, v.25 n.8, p.631-651, November, 2008