Reconstructing curved surfaces from specular reflection patterns using spline surface fitting of normals

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Reconstructing curved surfaces from specular reflection patterns using spline surface fitting of normals

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International Conference on Computer Graphics and Interactive Techniques archive
Proceedings of the 23rd annual conference on Computer graphics and interactive techniques table of contents

Pages: 335 - 342

Year of Publication: 1996

ISBN:0-89791-746-4

Authors

Mark A. Halstead	Apple Computer, 1 Infinite Loop M/S 301-3J, Cupertino, CA and Computer Science Division, University of California, Berkeley, CA
Brain A. Barsky	Computer Science Division, University of California, Berkeley, CA and School of Optometry, University of California, Berkeley, CA
Stanley A. Klein	School of Optometry, University of California, Berkeley, CA
Robert B. Mandell	School of Optometry, University of California, Berkeley, CA

Sponsor

SIGGRAPH: ACM Special Interest Group on Computer Graphics and Interactive Techniques

Publisher

ACM New York, NY, USA

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Downloads (6 Weeks): 12, Downloads (12 Months): 68, Citation Count: 13

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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.

	1	ALTSCHULER, M., ALTSCHULER, B., AND TABOADA, J. Laser electrooptic system for rapid three-dimensional (3-D) topographic mapping of surfaces. Optical Engineering 20, 6 (1981), 953-961.
	2	BARSKY, B. A., MANDELL, R. B., AND KLEIN, S. A. Corneal shape illusion in keratoconus. Invest Opthalmol Vis Sci 36 Suppl.:5308 (1995).
	3	Richard H. Bartels , John C. Beatty , Brian A. Barsky, An introduction to splines for use in computer graphics & geometric modeling, Morgan Kaufmann Publishers Inc., San Francisco, CA, 1987
	4	BELIN, M. W., LITOFF, D., AND STRODS, S. J. The PAR technology corneal topography system. Refract Corneal Surg 8 (1992), 88- 96.
	5	Andrew Blake , Andrew Zisserman, Visual reconstruction, MIT Press, Cambridge, MA, 1987
	6	BOLLE, R., AND VEMURI, B. On three-dimensional surface reconstruction methods. IEEE Trans. PAMI 11, 8, 840-858.
	7	BRINKLEY, J. Knowledge-driven ultrasonic three-dimensional organ modeling. IEEE Trans. PAMI 7, 4, 431-441.
	8	CHENG, F., AND BARSKY, B. A. Interproximation: Interpolation and approximation using cubic spline curves. Computer-Aided Design 23, 10 (1991), 700-706.
	9	COHEN, E., LYCHE, T., AND RIESENFELD, R. Discrete B-splines and subdivision techniques in computer aided geometric design and computer graphics. Computer Graphics and Image Processing 14 (1980), 87-111.
	10	Doss, J. D., HUTSON, R. L., ROWSEY, J. J., AND BROWN, D. R. Method for calculation of corneal profile and power distribution. Arch Ophthalmol 99 (1981), 1261-5.
	11	FAVARDIN, C. Determination automatique de structures geometriques destinees a la reconstruction de courbes et de surfaces a partir de donnees ponctuelles. PhD thesis, Universite Paul Sabatier, Toulouse, France, 1993.
	12	GOSHTASBY, A. Surface reconstruction from scattered measuremeAts. SPIN 1830 (1992), 247-256.
	13	Hugues Hoppe , Tony DeRose , Tom Duchamp , Mark Halstead , Hubert Jin , John McDonald , Jean Schweitzer , Werner Stuetzle, Piecewise smooth surface reconstruction, Proceedings of the 21st annual conference on Computer graphics and interactive techniques, p.295-302, July 1994 [doi>10.1145/192161.192233]
	14	JARVIS. A perspective on range finding techniques for computer vision. IEEE Trans. PAMI 5, 2 (1983), 122-139.
	15	KLYCE, S.D. Computer-assisted corneal topography, highresolution graphic presentation and analysis of keratoscopy. Invest Ophthalmol Vis Sci 25 (1984), 1426-35.
	16	KOCH, D. D., FOULKS, G. N., AND MORAN, T. The corneal eyesys system: accuracy, analysis and reproducibility of first generation prototype. Refract Corneal Surg 5 (1989), 424-9.
	17	KRACHMER, J. H., FEDER, R. S., AND BELIN, M. W. Keratoconus and related noninflammatory corneal thinning disorders. Surv. Ophthalmol 28, 4 (1984), 293-322.
	18	MAGUIRE, L. J., AND BOURNE, W. D. Corneal topography of early keratoconus. Am J Ophthalmol 108 (1989), 107-12.
	19	MAMMONE, R. J., GERSTEN, M., GORMLEY, D. J., KOPLIN, R. S., AND LUBKIN, V. L. 3-D corneal modeling system. IEEE Trans Biomedical Eng 37 (1990), 66-73.
	20	MOORE, D., AND WARREN, J. Approximation of dense scattered data using algebraic surfaces. Tech. rep., TR 90-135, Rice University, 1990.
	21	Vaughan Pratt, Direct least-squares fitting of algebraic surfaces, Proceedings of the 14th annual conference on Computer graphics and interactive techniques, p.145-152, August 1987
	22	SATO, Y., KITAGAWA, H., AND FUJITA, H. Shape measurement of curved objects using multiple slit-ray projections. IEEE Trans. PAMI g, 6 (1982), 641-649.
	23	Francis J M Schmitt , Brian A. Barsky , Wen-hui Du, An adaptive subdivision method for surface-fitting from sampled data, Proceedings of the 13th annual conference on Computer graphics and interactive techniques, p.179-188, August 1986
	24	TAUBIN, G. An improved algorithm for algebraic curve and surface fitting. In Proc. gth International Conf. on Comp. Vision, Berlin (1993), pp. 658-665.
	25	Demetri Terzopoulos, Regularization of inverse visual problems involving discontinuities, IEEE Transactions on Pattern Analysis and Machine Intelligence, v.8 n.4, p.413-242, July 1986 [doi>10.1109/TPAMI.1986.4767807]
	26	Leonardo C Topa , Robert J Schalkoff, An analytical approach to the determination of planar surface orientation using active-passive image pairs, Computer Vision, Graphics, and Image Processing, v.35 n.3, p.404-418, Sept. 1986 [doi>10.1016/0734-189X(86)90008-3]
	27	Greg Turk , Marc Levoy, Zippered polygon meshes from range images, Proceedings of the 21st annual conference on Computer graphics and interactive techniques, p.311-318, July 1994 [doi>10.1145/192161.192241]
	28	VaN SaaRLOOS, P. P., aND CONSTABLE, I. Improved method for calculation of corneal topography for any photokeratoscope geometry. Optom Vis Sci 68 (1991), 960-6.
	29	WANG, J., RICE, D. A., AND KLYCE, S. D. A new reconstruction algorithm for improvement of corneal topographical analysis. Refract. Corneal Surg 5 (1989), 379-387.
	30	WARNICKI, J. W., REHKOPF, P. G., AND CURTIN, S. n. Corneal topography using computer analyzed rasterographic images. Am. J. Opt 27 (1988), 1125-1140.
	31	WILSON, S. E., AND KLYCE, S. D. Advances in the analysis of corneal topography. Surv. Ophthalmol. 35 (1991), 269-277.

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	Aaron Lefohn , Brian Budge , Peter Shirley , Richard Caruso , Erik Reinhard, An Ocularist's Approach to Human Iris Synthesis, IEEE Computer Graphics and Applications, v.23 n.6, p.70-75, November 2003
	Silvio Savarese , Min Chen , Pietro Perona, Local Shape from Mirror Reflections, International Journal of Computer Vision, v.64 n.1, p.31-67, August 2005
	Michael F. Deering, A photon accurate model of the human eye, ACM Transactions on Graphics (TOG), v.24 n.3, July 2005
	Marco Tarini , Hendrik P. A. Lensch , Michael Goesele , Hans-Peter Seidel, 3D Acquisition of mirroring objects using striped patterns, Graphical Models, v.67 n.4, p.233-259, July 2005
	Kiriakos N. Kutulakos , Eron Steger, A Theory of Refractive and Specular 3D Shape by Light-Path Triangulation, International Journal of Computer Vision, v.76 n.1, p.13-29, January 2008
	Ko Nishino , Shree K. Nayar, Corneal Imaging System: Environment from Eyes, International Journal of Computer Vision, v.70 n.1, p.23-40, October 2006
	E. Tosun , Y. I. Gingold , J. Reisman , D. Zorin, Shape optimization using reflection lines, Proceedings of the fifth Eurographics symposium on Geometry processing, July 04-06, 2007, Barcelona, Spain
	J. Lellmann , J. Balzer , A. Rieder , J. Beyerer, Shape from Specular Reflection and Optical Flow, International Journal of Computer Vision, v.80 n.2, p.226-241, November 2008
	Jan Erik Solem , Henrik Aanaes , Anders Heyden, Variational Surface Interpolation from Sparse Point and Normal Data, IEEE Transactions on Pattern Analysis and Machine Intelligence, v.29 n.1, p.181-184, January 2007
	Jing Wang , Kristin J. Dana, Relief Texture from Specularities, IEEE Transactions on Pattern Analysis and Machine Intelligence, v.28 n.3, p.446-457, March 2006