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Chromatic adaptation model for the variations of the luminance of the same chromaticity illuminants  

Kim Eun-Su (Dept. of Electronics Engineering Kyungpook)
Jang Soo-Wook (Dept. of Electronics Engineering Kyungpook)
Lee Sung-Hak (Dept. of Electronics Engineering Kyungpook)
Sohng Kyu-lk (Dept. of Electronics Engineering Kyungpook)
Publication Information
Journal of the Institute of Electronics Engineers of Korea SP / v.42, no.4, 2005 , pp. 31-38 More about this Journal
Abstract
In this paper, we propose the chromatic adaptation models (CAM) for the variations of the luminance levels. A chromatic adaptation model, CAM$\Delta$Y , is proposed according to the change of luminance level under the same illuminants. The proposed model is obtained by the transform the test colors of the high luminance into the corresponding colors of the low luminance. In the proposed model, the optimal coefficients are obtained from the corresponding colors data of the Breneman's experiments. In the experimental results, we confined that the chromaticity errors, $\Delta$u'v', between the predicted colors by the proposed model and the corresponding colors of the Breneman's experiments are 0.004 in u'v' chromaticity coordinates. The prediction performance of the proposed model is excellent because this error is the threshold value that two adjacent color patches can be distinguished. Additionally, we also propose equal-whiteness CCT curves (EWCs) by CAM$\Delta$Y according to the luminance levels of the surround viewing conditions. And the proposed EWCs can be used as the theoretical standard which determines the reference white of the color display devices.
Keywords
human visual system;
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1 大西地, “カラ-テレビにおける好みの白測定,” テレビ全大,pp. 15-16, 1976
2 C. J. Hirsch, 'The chromaticity of reference white in color television,' J. of SMPTE, vol. 77, pp. 702-713, July 1968   DOI
3 E.-S. Kim, S.-W. Jang, Y.-D. Kwon, C.-H. Han, and K.-I. Sohng, 'Corresponding-color reproduction model according to surround viewing conditions,' IEICE Trans. Fund., vol.E87-A, no. 6, pp. 1514-1519, June 2004
4 L. E. DeMarsh and J. E. Pinney, 'Studies of some colorimetric problems in color television,' J. of SMPTE, vol. 79, pp. 338-342, April 1970   DOI
5 C. B. Neal, 'Television colorimetry for receiver engineers,' IEEE Trans. BTR, vol. BTR-19, pp. 149-162, Aug. 1973   DOI   ScienceOn
6 M. D. Fairchild, 'A model of incomplete chromatic adaptation,' Proc. the 22nd Session of the CIE, Melbourne, pp. 33-34, 1991
7 M. D. Fairchild, 'Formulation and testing of an incomplete-chromatic-adaptation model,' Color Res. Appl., vol. 16, pp. 243-250, 1991   DOI
8 CIE TC1-34 Final Report, The CIE 1997 Interim Colour Appearance Model (Simple Version), CIECAM97s, 1998
9 권용대, '조명에 따른 디스플레이 대응색 재현 모델,' 경북대학교 전자공학과 박사학위논문, 2001년 12월
10 최덕규, '시각계 색 순응을 고려한 텔레비전 수상기에서의 색 재현,' 경북대학교 전자공학과 박사학위논문, 1997년 6월
11 E. J. Breneman, 'Corresponding chromaticities for different states of adaptation to complex visual fields,' J. of Opt. Soc. Am, vol. 4, pp. 1115-1129, June 1987   DOI
12 C. J. Bartleson, 'Changes in color appearance with variations in chromatic adaptation,' Color Res. Appl., vol. 4, pp. 119-138, Fall 1979   DOI
13 G. Wyszecki and W. S. Stiles, Color Science:Concepts and Methods, Quantitative Data and Formulae, John Wiley & Sons, New York, 1982, pp. 117-451
14 D. L. MacAdam, Color Measurement, Springer-Verlag Berlin Heidelberg, New York, 1981, pp. 200-208
15 C. J. Bartleson, 'Comparison of chromatic-adaptation transforms,' Color Res. Appl., vol. 3, pp. 129-136, Fall 1978   DOI
16 J. Hernandez-Andres, J. Romero, and J. L. Nieves, 'Color and spectral analysis of daylight in southern Europe,' J. of Opt. Soc. Am., vol. 18, pp. 1325-1335, 2001   DOI
17 송규익, 색채 디스플레이 공학, 도서출판 화성, 대구, 2002
18 E. R. Dixon, 'Spectral distribution of Australian daylight,' J. of Opt. Soc. Am., vol. 68, pp. 437-450, 1978   DOI
19 C. J. Bartleson, 'Predicting corresponding colors with changes in adaptation,' Color Res. Appl, vol. 4, pp. 143-155, Fall 1979   DOI
20 C. A. Poynton, A Technical Introduction to Digital Video, John Wiley & Sons, pp. 85-86, 1996
21 M. D. Fairchild, 'Considering the surround in device-independent color imaging,' Color Res. Appl, vol. 20, pp. 352-363, 1995   DOI
22 D. M. Purdy, 'Spectral hue as a function of intensity,' Am. J. of Psych., vol. 43, pp. 541-559, 1931   DOI   ScienceOn
23 H. Helson, 'Rundamental problem in color vision. I. The principle governing changes in hue, saturation, and lightness of non-selective samples in chromatic illumination,' J. of Exp. Psych., vol. 23, pp. 439-477, 1938   DOI
24 J. C. Stevens and S. S. Stevens, 'Brightness functions: Effects of adaptation,' J. of Opt. Soc. Am, vol. 53, pp. 375-385, 1963   DOI
25 R. W. G. Hunt, 'Light and dark adaptation and the perception of color,' J. of Opt. Soc. Am., vol. 42, pp. 190-199, 1952   DOI
26 R. W. G. Hunt, The Reproduction of Colour in Photography, Printing & Television, Fountain Press, England, pp. 177-196, 1987
27 M. D.Fairchild, Color Appearance Models, Addison-Wesley, New York, pp. 173-345, 1998
28 M. Stokes and M. Anderson, 'A standard default color space for the internet-sRGB,' http://www. w3. org/Graphics/Color/sRGB. html, 1996
29 M. D. Fairchild and E. Pirrotta, 'Prediction the lightness of chromatic object colors using CIELAB,' Color Res. Appl., vol. 16, pp. 385-393, 1991   DOI