Eric J. Stollnitz
- 1.Harold Boll. A Color to Colorant Transformation for a Seven Ink Process. In Device-Independent Color Imaging, volume 2170 of Proceedings of the SPIE, pages 108-118, 1994.Google Scholar
Cross Ref
- 2.R J. Burt and E. H. Adelson. The Laplacian Pyramid as a Compact Image Code. IEEE Transactions on Communications, 31(4):532-540, April 1983.Google ScholarCross Ref
- 3.Lawrence Davis. Handbook of Genetic Algorithms. Van Nostrand Reinhold, New York, 1991.Google Scholar
- 4.M.D. Fairchild and R. S. Berns. Image Color-Appearance Specification Through Extension of CIELAB. Color Research and Application, 18(3):178-190, June 1993.Google ScholarCross Ref
- 5.R. S. Gentile, E. Walowit, and J. R Allebach. A Comparison of Techniques for Color Gamut Mismatch Compensation. Journal of Imaging Technology, 16(5): 176-181, October 1990.Google Scholar
- 6.Arthur C. Hardy and F. L. Wurzburg, Jr. Color Correction in Color Printing. Journal of the Optical Society of America, 38(4):300-307, April 1948.Google ScholarCross Ref
- 7.Paul Heckbert. Color Image Quantization for Frame Buffer Display. In Proceedings of SIGGRAPH 82, pages 297-307, 1982. Google ScholarDigital Library
- 8.R. W. G. Hunt. Revised Colour-Appearance Model for Related and Unrelated Colours. Color Research and Application, 16(3):146-165, June 1991.Google ScholarCross Ref
- 9.Kansei Iwata and Gabriel Marcu. Computer Simulation of Printed Colors on Textile Materials. In Color Hard Copy and Graphic Arts III, volume 2171 of Proceedings of the SPIE, pages 228-238, 1994.Google ScholarCross Ref
- 10.Tony Johnson. A Complete Colour Reproduction Model for Graphic Arts. In Proceedings of the Technical Association of the Graphic Arts, pages 1061-1076, 1996.Google Scholar
- 11.D.B. Judd and G. Wyszecki. Color in Business, Science, andlndustry. John Wiley and Sons, New York, 1975.Google Scholar
- 12.Henry R. Kang. Comparisons of Color Mixing Theories for Use in Electronic Printing. In Proceedings of the IS&T/SID Color Imaging Conference: Transforms & Transportability of Color, pages 78-82, 1993.Google Scholar
- 13.Gustav Kortfim. Reflectance Spectroscopy: Principles, Methods, Applications, chapter 4, pages 103-169. Springer, New York, 1969.Google Scholar
- 14.R Laihanen. Colour Reproduction Theory Based on the Principles of Colour Science. In Proceedings of the International Association of Research Institutes for the Graphic Arts Industry, volume 19, pages 1-36, 1987.Google Scholar
- 15.Bruce J. Lindbloom. Accurate Color Reproduction for Computer Graphics Applications. In Proceedings of SIGGRAPH 89, pages 117- 126, 1989. Google ScholarDigital Library
- 16.Yan Liu. Spectral Reflectance Modification of Neugebauer Equations. In Proceedings of the Technical Association of the Graphic Arts, pages 154-172, 1991.Google Scholar
- 17.Lindsay W. MacDonald. Gamut Mapping in Perceptual Color Space. In Proceedings of the IS&T/SID Color Imaging Conference: Transforms & Transportability of Color, pages 193-196, 1993.Google Scholar
- 18.Marc Mahy and Paul Delabastita. Inversion of the Neugebauer Equations. Color Research and Application, 21(6):401-411, December 1996.Google ScholarCross Ref
- 19.Gabriel Marcu and Satoshi Abe. Color Designing and Simulation in Non-Conventional Printing Process. In Applications of Digital Image Processing XVII, volume 2298 of Proccedings of the SPIE, pages 216- 223, 1994.Google ScholarCross Ref
- 20.Ethan D. Montag and Mark D. Fairchild. Psychophysical Evaluation of Gamut Mapping Techniques Using Simple Rendered Images and Artificial Gamut Boundaries. IEEE Transactions on Image Processing, 6(7):977-989, July 1997. Google ScholarDigital Library
- 21.H. E. J. Neugebauer. Die Theoretischen Grundlagen des Mehrfarbenbuchdrucks (The Theoretical Foundation for Multicolor Printing). Zeitschrift fuer Wissenschaftliche Photographie, 36(4):73-89, 1937. Reprinted in Neugebauer Memorial Seminar on Color Reproduction, volume 1184 of Proceedings of the SPIE, pages 194-202. SPIE, Bellingham, WA, 1990.Google Scholar
- 22.Victor Ostromoukhov. Chromaticity Gamut Enhancement by Heptatone Multi-color Printing. In Device-Independent Color Imaging and Imaging Systems Integration, volume 1909 of Proceedings of the SPIE, pages 139-151, 1993.Google ScholarCross Ref
- 23.Joanna L. Power, Brad S. West, Eric J. Stollnitz, and David H. Salesin. Reproducing Color Images as Duotones. In Proceedings of SIG- GRAPH 96, pages 237-248, 1996. Google ScholarDigital Library
- 24.William H. Press, Brian R Flannery, Saul A. Teukolsky, and William T. Fetterling. Numerical Recipes. Cambridge University Press, New York, second edition, 1992.Google ScholarDigital Library
- 25.J. L. Saunderson. Calculation of the Color of Pigmented Plastics. Journal of the Optical Society of America, 32(12):727-736, December 1942.Google ScholarCross Ref
- 26.Eric J. Stollnitz. Reproducing Color Images with Custom Inks. Ph.D. thesis, University of Washington, 1998. Google ScholarDigital Library
- 27.Maureen C. Stone, William B. Cowan, and John C. Beatty. Color Gamut Mapping and the Printing of Digital Color Images. ACM Transactions on Graphics, 7(4):249-292, October 1988. Google ScholarDigital Library
- 28.Atsushi Takaghi, Toru Ozeki, Yoshinori Ogata, and Sachie Minato. Faithful Color Printing for Computer Generated Image Syntheses with Highly Saturated Component Inks. In Proceedings of the IS&T/SID Color Imaging Conference: Color Science, Systems and Applications, pages 108-111, 1994.Google Scholar
- 29.M. Wolski, J. R Allebach, and C. A. Bouman. Gamut Mapping: Squeezing the Most out of Your Color System. In Proceedings of the IS&T/SID Color Imaging Conference: Color Science, Systems andApplications, pages 89-92, 1994.Google Scholar
Index Terms
- Reproducing color images using custom inks
Recommendations
Reproducing color images as duotones
SIGGRAPH '96: Proceedings of the 23rd annual conference on Computer graphics and interactive techniquesColor images visible under UV light
SIGGRAPH '07: ACM SIGGRAPH 2007 papersThe present contribution aims at creating color images printed with fluorescent inks that are only visible under UV light. The considered fluorescent inks absorb light in the UV wavelength range and reemit part of it in the visible wavelength range. In ...
Color image enhancement with high saturation using piecewise linear gamut mapping
AbstractMost of the color image enhancement algorithms are implemented in two stages: gray scale image enhancement, which finds the target intensity, and then gamut mapping of the original color coordinates to the target. Therefore, hue ...
Comments