Available in electronic format
Available in print format		 Transacrions of the American Mathematical Society
Transactions of the American Mathematical Society
ISSN 1088-6850(e) ISSN 0002-9947(p)
Previous issue | Table of contents | Next issue
Articles in press | Recently posted articles | Most recent issue | All issues
Next Article
     

Delaunay configurations and multivariate splines: A generalization of a result of B. N. Delaunay

Author(s): Marian Neamtu
Journal: Trans. Amer. Math. Soc. 359 (2007), 2993-3004.
MSC (2000): Primary 41A15, 41A63; Secondary 05B45, 52C22, 65D17, 65D18
Posted: February 8, 2007
Retrieve article in: PDF DVI PostScript

Abstract | References | Similar articles | Additional information

Abstract: In the 1920s, B. N. Delaunay proved that the dual graph of the Voronoi diagram of a discrete set of points in a Euclidean space gives rise to a collection of simplices, whose circumspheres contain no points from this set in their interior. Such Delaunay simplices tessellate the convex hull of these points. An equivalent formulation of this property is that the characteristic functions of the Delaunay simplices form a partition of unity. In the paper this result is generalized to the so-called Delaunay configurations. These are defined by considering all simplices for which the interiors of their circumspheres contain a fixed number of points from the given set, in contrast to the Delaunay simplices, whose circumspheres are empty. It is proved that every family of Delaunay configurations generates a partition of unity, formed by the so-called simplex splines. These are compactly supported piecewise polynomial functions which are multivariate analogs of the well-known univariate B-splines. It is also shown that the linear span of the simplex splines contains all algebraic polynomials of degree not exceeding the degree of the splines.

References:

1.
Boissonnat, J.-D., O. Devillers, and M. Teillaud, A semidynamic construction of higher-order Voronoi diagrams and its randomized analysis, Algorithmica 9 (1993), 329-356. MR 1208566 (94k:68182)

2.
Boor, C. de, Splines as linear combinations of B-splines. A survey, in Approximation Theory, II, G. G. Lorentz, C. K. Chui, and L. L. Schumaker (eds.), Academic Press, New York, 1976, 1-47. MR 0467092 (57:6959)

3.
Curry, H. B., and I. J. Schoenberg, On Pólya frequency functions IV: The fundamental spline functions and their limits, J. Analyse Math. 17 (1966), 71-107. MR 0218800 (36:1884)

4.
Dahmen, W., and C. A. Micchelli, Statistical encounters with B-splines, in Function Estimates (Arcata, Calif., 1985), Contemp. Math., 59, Amer. Math. Soc., Providence, 1986, 17-48. MR 0870446 (88d:65022)

5.
Dahmen, W., C. A. Micchelli, and H.-P. Seidel, Blossoming begets B-splines built better by B-patches, Math. Comp. 59 (1992), 97-115. MR 1134724 (93b:41014)

6.
Delaunay, B., Sur la sphère vide, Bull. Acad. Sci. USSR (VII), Classe Sci. Mat. Nat., 1934, 793-800.

7.
Lee, D.-T., On $ k$-nearest neighbor Voronoi diagrams in the plane, IEEE Trans. Comp. 31 (1982), 478-487. MR 0669964 (83m:68157)

8.
Micchelli, C. A., A constructive approach to Kergin interpolation in $ \mathbb{R}^k$: multivariate B-splines and Lagrange interpolation, Rocky Mountain J. Math. 10 (1980), 485-497. MR 0590212 (84i:41002)

9.
Micchelli, C. A., Mathematical Aspects of Geometric Modeling, CBMS-NSF Regional Conference Series in Applied Mathematics, 65, SIAM, Philadelphia, 1995. MR 1308048 (95i:65036)

10.
Neamtu, M., What is the natural generalization of univariate splines to higher dimensions?, in Mathematical Methods for Curves and Surfaces: Oslo 2000, T. Lyche and L. L. Schumaker (eds.), Vanderbilt University Press, Nashville, TN, 2001, 355-392. MR 1858970

11.
Okabe, A., B. Boots, and K. Sugihara, Spatial Tessellations: Concepts and Applications of Voronoi Diagrams, 2nd ed., Wiley, Chichester, England, 2000. MR 1770006 (2001c:52013)

12.
Preparata, F. P., and M. I. Shamos, Computational Geometry, Springer, 1985. MR 0805539 (87d:68102)

13.
Ramshaw, L., Blossoms are polar forms, Comput. Aided Geom. Design 6 (1989), 323-358. MR 1030618 (91d:65026)

14.
Sabin, M., Open questions in the application of multivariate B-splines, in Mathematical Methods in Computer Aided Geometric Design, T. Lyche and L. L. Schumaker (eds.), Academic Press, New York, 1989, 529-537. MR 1022732 (90k:65050)

15.
Schumaker, L. L., Spline Functions: Basic Theory, Interscience, New York, 1981. Reprinted by Krieger, Malabar, Florida, 1993. MR 0606200 (82j:41001)

16.
Seidel, H.-P., Polar forms and triangular B-spline surfaces, in Blossoming: The New Polar-Form Approach to Spline Curves and Surfaces SIGGRAPH '91, Course Notes #26, ACM SIGGRAPH, 1991.

17.
Shamos, M. I., and D. Hoey, Closest-point problems, in IEEE Symposium on Foundations of Computer Science, 1975, 151-162. MR 0426498 (54:14441)

Similar Articles:

Retrieve articles in Transactions of the American Mathematical Society with MSC (2000): 41A15, 41A63, 05B45, 52C22, 65D17, 65D18

Retrieve articles in all Journals with MSC (2000): 41A15, 41A63, 05B45, 52C22, 65D17, 65D18

Additional Information:

Marian Neamtu
Affiliation: Department of Mathematics, Center for Constructive Approximation, Vanderbilt University, Nashville, Tennessee 37240
Email: neamtu@math.vanderbilt.edu

DOI: 10.1090/S0002-9947-07-03976-1
PII: S 0002-9947(07)03976-1
Keywords: Delaunay configuration, Delaunay triangulation, higher-order Voronoi diagram, multivariate spline, polynomial reproduction, simplex spline
Received by editor(s): February 12, 2004
Received by editor(s) in revised form: February 4, 2005
Posted: February 8, 2007
Additional Notes: This work was supported by the NSF under grant CCF-0204174.
Copyright of article: Copyright 2007, American Mathematical Society
The copyright for this article reverts to public domain after 28 years from publication.

  AMS Website Logo Small Comments: webmaster@ams.org
© Copyright 2008, American Mathematical Society
Privacy Statement 		Search the AMSPowered by Google