Rethinking Colour Constancy

Logvinenko, Alexander D.; Funt, Brian V.; Mirzaei, Hamidreza; Tokunaga, Rumi

doi:10.1371/journal.pone.0135029

Cited by 37 publications

(46 citation statements)

References 38 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Color constancy has been extensively studied in human as well as in computer vision, and remains the subject of debate (Logvinenko et al 2015). Many theories and approaches to color constancy attempt to estimate the illuminant from the visual scene (Land 1964;Van De Weijer and Gevers 2005;Provenzi et al 2008), and then discount it from the AI.…”

Section: Introductionmentioning

confidence: 99%

Master thesis: Extensions of a linear model of surface reflectance

Flachot¹

2019

Preprint

View full text Add to dashboard Cite

Philipona O'Regan recently proposed a linear model of surface reflectance as it is sensed by the human eyes. In their model, the three dimensional cone response to reflected light is accurately approximated by a linear transformation of the three dimensional response to illumination. The geometrical properties of this linear transformation, such as singularity, correlate with psychophysical results on focal colors and unique hues. Later, Vazquez-Corral et al. built a bridge between Philipona & O'Regan's model and von Krieslike approaches to color constancy in computer vision by showing that the linear operators could be diagonalized in a common basis.However both of these studies required specifying a particular dataset of illuminants. We will show in this paper that it is possible to compute adequate linear operators and a common basis for diagonalization without specifying any particular set of illuminants, thus enhancing their generalizability to illuminant changes, while maintaining correlations with features of the human color vision. Further analysis of the characteristics of singularity in reflection properties will also be presented.

show abstract

Section: Introductionmentioning

confidence: 99%

Master thesis: Extensions of a linear model of surface reflectance

Flachot¹

2019

Preprint

View full text Add to dashboard Cite

show abstract

“…As L&T point out, a perfect asymmetric match will usually be impossible due to metamer mismatching (i.e., the fact that two different reflectances may reflect metameric lights under one illuminant, but non-metameric lights under a second illuminant). Further analysis of the effect of metamer mismatching in the context of this experiment is provided by Logvinenko et al [7].…”

Section: Introductionmentioning

confidence: 99%

“…Derhak and Berns define the goal of a MAT as "…to predict material constancy or how sensor excitations for an object color change with changes in observing conditions" [10]. The problem with this definition is, as established by Logvinenko et al [7], that as a result of metamer mismatching intrinsic object colors that are independent of the illuminant simply do not exist-hence material constancy in the Derhak and Berns sense does not exist either, since from such material constancy intrinsic object color would immediately follow.…”

Section: Introductionmentioning

confidence: 99%

Computational color prediction versus least-dissimilar matching

Roshan

Funt

2018

J. Opt. Soc. Am. A

Self Cite

View full text Add to dashboard Cite

The performance of color prediction methods CIECAM02, KSM, Waypoint, Best Linear, Metamer Mismatch Volume Center, and Relit color signal are compared in terms of how well they explain Logvinenko and Tokunaga's asymmetric color matching results [Seeing Perceiving24, 407 (2011)]. In their experiment, four observers were asked to determine (three repeats) for a given Munsell paper under a test illuminant which of 22 other Munsell papers was the least-dissimilar under a match illuminant. Their use of "least-dissimilar" as opposed to "matching" is an important aspect of their experiment. Their results raise several questions. Question 1: Are observers choosing the original Munsell paper under the match illuminant? If they are, then the average (over 12 matches) color signal (i.e., cone LMS or CIE XYZ) made under a given illuminant condition should correspond to that of the test paper's color signal under the match illuminant. Computation shows that the mean color signal of the matched papers is close to the color signal of the physically identical paper under the match illuminant. Question 2: Which color prediction method most closely predicts the observers' average least-dissimilar match? Question 3: Given the variability between observers, how do individual observers compare to the computational methods in predicting the average observer matches? A leave-one-observer-out comparison shows that individual observers, somewhat surprisingly, predict the average matches of the remaining observers better than any of the above color prediction methods.

show abstract

“…Another term for white balancing in the context of digital images is color constancy. Hence the proposed method also addresses the color constancy problem; however, we avoid further use of that term since Logvinenko et al [5] proved that color constancy defined as the determination of the intrinsic color of surfaces from trichromatic data simply does not exist in principle. Our 'color constancy' goal, therefore, is not to extract intrinsic surface properties but rather to remove color casts from images.…”

Section: Introductionmentioning

confidence: 99%

Colorizing Color Images

Zhu¹,

Funt²

2018

Self Cite

View full text Add to dashboard Cite

This paper describes a method of improving the quality of the color in color images by colorizing them. In particular, color quality may suffer from improper white balance and other factors such as inadequate camera characterization. Colorization generally refers to the problem of turning a luminance image into a realistic looking color image and impressive results have been reported in the computer vision literature. Based on the assumption that if colorization can successfully predict colors from luminance data alone then it should certainly be able to predict colors from color data, the proposed method employs colorization to 'color' color images. Tests show that the proposed method quite effectively removes color casts-including spatially varying color casts-created by changes in the illumination. The colorization method itself is based on training a deep neural network to learn the connection between the colors in an improperly balanced image and those in a properly balanced one. Unlike many traditional white-balance methods, the proposed method is image-inimage-out and does not explicitly estimate the chromaticity of the illumination nor apply a von-Kries-type adaptation step. The colorization method is also spatially varying and so handles spatially varying illumination conditions without further modification.

show abstract

Rethinking Colour Constancy

Cited by 37 publications

References 38 publications

Master thesis: Extensions of a linear model of surface reflectance

Master thesis: Extensions of a linear model of surface reflectance

Computational color prediction versus least-dissimilar matching

Colorizing Color Images

Contact Info

Product

Resources

About