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MacAdam ellipse

December 15, 2023

In the study of color vision, a MacAdam ellipse is roughly a region on a chromaticity diagram which contains all colors which are indistinguishable, to the average human eye, from the color at the center of the ellipse. Specifically, it is the standard deviation of a number of experimental color matches to the central color assuming a bivariate normal distribution of these match points. A MacAdam ellipse thus contains about 67% of the color match points. A 2X MacAdam ellipse will contain about 95% of the match points, and a 3X MacAdam ellipse will contain about 99% of the match points. The contour of the ellipse is therefore a measure of the just-noticeable differences of chromaticity. Standard Deviation Color Matching in LED lighting uses deviations relative to MacAdam ellipses to describe color precision of a light source.[1]

MacAdam ellipses for one of MacAdam's test participants, Perley G. Nutting (observer "PGN"), plotted on the CIE 1931 xy chromaticity diagram. The ellipses are ten times their actual size, as depicted in MacAdam's paper.

History edit

In the study of color perception, it is essential to develop a method of specifying a particular color such that it can be differentiated from all other colors. It has been found that three quantities are needed to specify a particular color. The relative amounts of red, green and blue in a color will serve to specify that color completely. This question was first approached by a number of researchers in the 1930s, and their results were formalized in the specification of the CIE XYZ color space.

The concept of a color space can similarly be used to determine how distant one color is from another. This particular question was considered by researchers dating back to Helmholtz and Schrödinger,[2] and later in industrial applications,[3] but experiments by Wright and Pitt,[4] and David MacAdam provided much-needed empirical support.[5]

Procedure edit

MacAdam set up an experiment in which a trained observer viewed two different colors, at a fixed luminance of about 48 cd/m2. One of the colors (the "test" color) was fixed, but the other was adjustable by the observer, and the observer was asked to adjust that color until it matched the test color. This match was, of course, not perfect, since the human eye, like any other instrument, has limited accuracy. It was found by MacAdam, however, that the standard deviation of the matches made by the observer fell into an ellipse on the CIE 1931 chromaticity diagram. The measurements were made at 25 points on the chromaticity diagram, and it was found that the size and orientation of the ellipses on the diagram varied widely depending on the test color. These 25 ellipses measured by MacAdam, for a particular observer, are shown on the chromaticity diagram above.

Extension to three dimensions edit

A more general concept is that of "discrimination ellipsoids" in the entire three-dimensional color space, which would include the ability of an observer to discriminate between two different luminances of the same color.[6] Such measurements were carried out, among others, by Brown and MacAdam in 1949,[7] Davidson in 1951,[8] Brown in 1957,[9] and by Wyszecki and Fielder in 1971.[10] It was found that the discrimination ellipsoids yielded relatively unchanging discrimination ellipses in chromaticity space for luminances between 3 and 30 cd/m2.[7]

Eccentricity Dependence edit

The original experiment carried out by MacAdam limited the field of view to be 2°,[5] essentially giving the ellipse estimations at the foveal vision. A recent work examined the eccentricity dependency of color discrimination using a Virtual Reality device.[11] Unsurprisingly, the discrimination ellipses grow in size as the eccentricity increases, because the human visual acuity drops sharply with eccentricity. The study also builds a computational model that predicts the ellipse shape given the test color and the eccentricity. The computational model is then used to wisely adjust pixel colors in the rendering pipeline to save display power, given that OLEDs power is strongly correlated with color. It is shown that one can save up to 20% of the display dynamic power without affecting the perceptual quality.

Effects in colour theory edit

MacAdam's results confirmed earlier suspicions that colour difference could be measured using a metric in a chromaticity space. A number of attempts have been made to define a color space which is not as distorted as the CIE XYZ space.[12] The most notable of these are the CIELUV and CIELAB color spaces. Although both of these spaces are less distorted than the CIE XYZ space, they are not completely free of distortion. This means that the MacAdam ellipses become nearly (but not exactly) circular in these spaces.

Using a Fisher information metric, da Fonseca et. al [13] investigated the degree to which MacAdam ellipses can be derived from the response functions of the retinal photoreceptors. It was demonstrated that photoreceptor absorption properties explain ≈ 87% of the variance of human color discrimination ability, as tested by previous behavioral experiments.

See also edit

References edit

  1. ^ "Talking Photometry - Colour Difference". Photometric Testing. Retrieved 26 March 2017.
  2. ^ Kühni, Rolf G. (March 2003). "6. Historical Development of Color Space and Color Difference Formulas". Color Space and Its Divisions. New York: Wiley. pp. 204–270. doi:10.1002/0471432261.ch6. ISBN 978-0-471-32670-0.
  3. ^ Judd, Deane B. (July 1939). "Specification of Color Tolerances at the National Bureau of Standards". The American Journal of Psychology. The American Journal of Psychology, Vol. 52, No. 3. 52 (3): 418–428. doi:10.2307/1416753. JSTOR 1416753.
  4. ^ Wright, William David; Pitt, F.H.G. (May 1934). "Hue-discrimination in normal colour-vision". Proceedings of the Physical Society. 46 (3): 459–473. Bibcode:1934PPS....46..459W. doi:10.1088/0959-5309/46/3/317.
  5. ^ a b MacAdam, David Lewis (May 1942). "Visual sensitivities to color differences in daylight" (abstract). JOSA. 32 (5): 247–274. doi:10.1364/JOSA.32.000247.
  6. ^ Günter Wyszecki and Walter Stanley Stiles, Color Science: Concepts and Methods, Quantitative Data and Formula (2nd edition), Wiley-Interscience. (July 28, 2000). ISBN 0-471-39918-3
  7. ^ a b Brown, Walter R.J.; MacAdam, David L. (October 1949). "Visual sensitivities to combined chromaticity and luminance differences" (abstract). JOSA. 39 (10): 808–834. doi:10.1364/JOSA.39.000808. PMID 18142394.
  8. ^ Davidson, Hugh R. (December 1951). "Calculation of Color Differences from Visual Sensitivity Ellipsoids" (abstract). JOSA. 41 (12): 1052–1056. doi:10.1364/JOSA.41.001052.
  9. ^ Brown, Walter R.J. (February 1957). "Color Discrimination of Twelve Observers" (abstract). JOSA. 47 (2): 137–143. doi:10.1364/JOSA.47.000137. PMID 13406654.
  10. ^ Wyszecki, Günter; Fielder, G. H. (September 1971). "New Color-Matching Ellipses" (abstract). JOSA. 61 (9): 1135–1152. doi:10.1364/JOSA.61.001135. PMID 5121883.
  11. ^ Duinkharjav, Budmonde; Chen, Kenneth; Tyagi, Abhishek; He, Jiayi; Zhu, Yuhao; Sun, Qi (2022). "Color-Perception-Guided Display Power Reduction for Virtual Reality". ACM Transactions on Graphics. 41 (6): 1–16. arXiv:2209.07610. doi:10.1145/3550454.3555473. S2CID 252355104.
  12. ^ Gravesen, Jens (November 2015). "The Metric of Color Space" (PDF). Graphical Models. 82: 77–86. doi:10.1016/j.gmod.2015.06.005. Retrieved 28 November 2023.
  13. ^ da Fonseca, Maria; Samengo, In´es (1 December 2016). "Derivation of human chromatic discrimination ability from an information-theoretical notion of distance in color space". Neural Computation. 28 (12): 2628–2655. arXiv:1611.07272. Retrieved 10 December 2023.

External links edit

  • MacAdam ellipses plotted with the "colour-science" Python package: in CIE 1960 UCS; in CIE 1976 UCS.

December 15, 2023
macadam, ellipse, this, article, tone, style, reflect, encyclopedic, tone, used, wikipedia, wikipedia, guide, writing, better, articles, suggestions, october, 2023, learn, when, remove, this, template, message, study, color, vision, roughly, region, chromatici. This article s tone or style may not reflect the encyclopedic tone used on Wikipedia See Wikipedia s guide to writing better articles for suggestions October 2023 Learn how and when to remove this template message In the study of color vision a MacAdam ellipse is roughly a region on a chromaticity diagram which contains all colors which are indistinguishable to the average human eye from the color at the center of the ellipse Specifically it is the standard deviation of a number of experimental color matches to the central color assuming a bivariate normal distribution of these match points A MacAdam ellipse thus contains about 67 of the color match points A 2X MacAdam ellipse will contain about 95 of the match points and a 3X MacAdam ellipse will contain about 99 of the match points The contour of the ellipse is therefore a measure of the just noticeable differences of chromaticity Standard Deviation Color Matching in LED lighting uses deviations relative to MacAdam ellipses to describe color precision of a light source 1 MacAdam ellipses for one of MacAdam s test participants Perley G Nutting observer PGN plotted on the CIE 1931 xy chromaticity diagram The ellipses are ten times their actual size as depicted in MacAdam s paper Contents 1 History 2 Procedure 3 Extension to three dimensions 4 Eccentricity Dependence 5 Effects in colour theory 6 See also 7 References 8 External linksHistory editIn the study of color perception it is essential to develop a method of specifying a particular color such that it can be differentiated from all other colors It has been found that three quantities are needed to specify a particular color The relative amounts of red green and blue in a color will serve to specify that color completely This question was first approached by a number of researchers in the 1930s and their results were formalized in the specification of the CIE XYZ color space The concept of a color space can similarly be used to determine how distant one color is from another This particular question was considered by researchers dating back to Helmholtz and Schrodinger 2 and later in industrial applications 3 but experiments by Wright and Pitt 4 and David MacAdam provided much needed empirical support 5 Procedure editMacAdam set up an experiment in which a trained observer viewed two different colors at a fixed luminance of about 48 cd m2 One of the colors the test color was fixed but the other was adjustable by the observer and the observer was asked to adjust that color until it matched the test color This match was of course not perfect since the human eye like any other instrument has limited accuracy It was found by MacAdam however that the standard deviation of the matches made by the observer fell into an ellipse on the CIE 1931 chromaticity diagram The measurements were made at 25 points on the chromaticity diagram and it was found that the size and orientation of the ellipses on the diagram varied widely depending on the test color These 25 ellipses measured by MacAdam for a particular observer are shown on the chromaticity diagram above Extension to three dimensions editA more general concept is that of discrimination ellipsoids in the entire three dimensional color space which would include the ability of an observer to discriminate between two different luminances of the same color 6 Such measurements were carried out among others by Brown and MacAdam in 1949 7 Davidson in 1951 8 Brown in 1957 9 and by Wyszecki and Fielder in 1971 10 It was found that the discrimination ellipsoids yielded relatively unchanging discrimination ellipses in chromaticity space for luminances between 3 and 30 cd m2 7 Eccentricity Dependence editThe original experiment carried out by MacAdam limited the field of view to be 2 5 essentially giving the ellipse estimations at the foveal vision A recent work examined the eccentricity dependency of color discrimination using a Virtual Reality device 11 Unsurprisingly the discrimination ellipses grow in size as the eccentricity increases because the human visual acuity drops sharply with eccentricity The study also builds a computational model that predicts the ellipse shape given the test color and the eccentricity The computational model is then used to wisely adjust pixel colors in the rendering pipeline to save display power given that OLEDs power is strongly correlated with color It is shown that one can save up to 20 of the display dynamic power without affecting the perceptual quality Effects in colour theory editMacAdam s results confirmed earlier suspicions that colour difference could be measured using a metric in a chromaticity space A number of attempts have been made to define a color space which is not as distorted as the CIE XYZ space 12 The most notable of these are the CIELUV and CIELAB color spaces Although both of these spaces are less distorted than the CIE XYZ space they are not completely free of distortion This means that the MacAdam ellipses become nearly but not exactly circular in these spaces Using a Fisher information metric da Fonseca et al 13 investigated the degree to which MacAdam ellipses can be derived from the response functions of the retinal photoreceptors It was demonstrated that photoreceptor absorption properties explain 87 of the variance of human color discrimination ability as tested by previous behavioral experiments See also editMetric tensor Tissot s indicatrix used to characterize distortions in map projections Mahalanobis distance using covariance to create a metricReferences edit Talking Photometry Colour Difference Photometric Testing Retrieved 26 March 2017 Kuhni Rolf G March 2003 6 Historical Development of Color Space and Color Difference Formulas Color Space and Its Divisions New York Wiley pp 204 270 doi 10 1002 0471432261 ch6 ISBN 978 0 471 32670 0 Judd Deane B July 1939 Specification of Color Tolerances at the National Bureau of Standards The American Journal of Psychology The American Journal of Psychology Vol 52 No 3 52 3 418 428 doi 10 2307 1416753 JSTOR 1416753 Wright William David Pitt F H G May 1934 Hue discrimination in normal colour vision Proceedings of the Physical Society 46 3 459 473 Bibcode 1934PPS 46 459W doi 10 1088 0959 5309 46 3 317 a b MacAdam David Lewis May 1942 Visual sensitivities to color differences in daylight abstract JOSA 32 5 247 274 doi 10 1364 JOSA 32 000247 Gunter Wyszecki and Walter Stanley Stiles Color Science Concepts and Methods Quantitative Data and Formula 2nd edition Wiley Interscience July 28 2000 ISBN 0 471 39918 3 a b Brown Walter R J MacAdam David L October 1949 Visual sensitivities to combined chromaticity and luminance differences abstract JOSA 39 10 808 834 doi 10 1364 JOSA 39 000808 PMID 18142394 Davidson Hugh R December 1951 Calculation of Color Differences from Visual Sensitivity Ellipsoids abstract JOSA 41 12 1052 1056 doi 10 1364 JOSA 41 001052 Brown Walter R J February 1957 Color Discrimination of Twelve Observers abstract JOSA 47 2 137 143 doi 10 1364 JOSA 47 000137 PMID 13406654 Wyszecki Gunter Fielder G H September 1971 New Color Matching Ellipses abstract JOSA 61 9 1135 1152 doi 10 1364 JOSA 61 001135 PMID 5121883 Duinkharjav Budmonde Chen Kenneth Tyagi Abhishek He Jiayi Zhu Yuhao Sun Qi 2022 Color Perception Guided Display Power Reduction for Virtual Reality ACM Transactions on Graphics 41 6 1 16 arXiv 2209 07610 doi 10 1145 3550454 3555473 S2CID 252355104 Gravesen Jens November 2015 The Metric of Color Space PDF Graphical Models 82 77 86 doi 10 1016 j gmod 2015 06 005 Retrieved 28 November 2023 da Fonseca Maria Samengo In es 1 December 2016 Derivation of human chromatic discrimination ability from an information theoretical notion of distance in color space Neural Computation 28 12 2628 2655 arXiv 1611 07272 Retrieved 10 December 2023 External links editMacAdam ellipses plotted with the colour science Python package in CIE 1960 UCS in CIE 1976 UCS Retrieved from https en wikipedia org w index php title MacAdam ellipse amp oldid 1189402113, wikipedia, wiki, book, books, library,

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