Effects of chromatic image statistics on illumination induced color differences.

We measure the color fidelity of visual scenes that are rendered under different (simulated) illuminants and shown on a calibrated LCD display. Observers make triad illuminant comparisons involving the renderings from two chromatic test illuminants and one achromatic reference illuminant shown simultaneously. Four chromatic test illuminants are used: two along the daylight locus (yellow and blue), and two perpendicular to it (red and green). The observers select the rendering having the best color fidelity, thereby indirectly judging which of the two test illuminants induces the smallest color differences compared to the reference. Both multicolor test scenes and natural scenes are studied. The multicolor scenes are synthesized and represent ellipsoidal distributions in CIELAB chromaticity space having the same mean chromaticity but different chromatic orientations. We show that, for those distributions, color fidelity is best when the vector of the illuminant change (pointing from neutral to chromatic) is parallel to the major axis of the scene's chromatic distribution. For our selection of natural scenes, which generally have much broader chromatic distributions, we measure a higher color fidelity for the yellow and blue illuminants than for red and green. Scrambled versions of the natural images are also studied to exclude possible semantic effects. We quantitatively predict the average observer response (i.e., the illuminant probability) with four types of models, differing in the extent to which they incorporate information processing by the visual system. Results show different levels of performance for the models, and different levels for the multicolor scenes and the natural scenes. Overall, models based on the scene averaged color difference have the best performance. We discuss how color constancy algorithms may be improved by exploiting knowledge of the chromatic distribution of the visual scene.

[1]  Jiebo Luo,et al.  A computationally efficient approach to indoor/outdoor scene classification , 2002, Object recognition supported by user interaction for service robots.

[2]  Marc Ebner,et al.  Color Constancy , 2007, Computer Vision, A Reference Guide.

[3]  Alexander Toet,et al.  A new universal colour image fidelity metric , 2003 .

[4]  G. Buchsbaum A spatial processor model for object colour perception , 1980 .

[5]  M. Lucassen,et al.  Quantifying color constancy: Evidence for nonlinear processing of cone-specific contrast , 1993, Vision Research.

[6]  Piet Bijl,et al.  The perception of static colored noise: Detection and masking described by CIE94 , 2008 .

[7]  Kinjiro Amano,et al.  Colour constancy from temporal cues: better matches with less variability under fast illuminant changes , 2001, Vision Research.

[8]  Marius Pedersen,et al.  Analysis of the Difference of Gaussians Model in Image Difference Metrics , 2010, CGIV/MCS.

[9]  Brian V. Funt,et al.  A Large Image Database for Color Constancy Research , 2003, CIC.

[10]  Karl R Gegenfurtner,et al.  Time course of chromatic adaptation for color appearance and discrimination , 2000, Vision Research.

[11]  D. Foster Color constancy , 2011, Vision Research.

[12]  Rainer Mausfeld,et al.  Second-Order Statistics of Colour Codes Modulate Transformations That Effectuate Varying Degrees of Scene Invariance and Illumination Invariance , 2002, Perception.

[13]  L. Arend,et al.  Simultaneous color constancy: paper with diverse Munsell values. , 1991, Journal of the Optical Society of America. A, Optics and image science.

[14]  Theo Gevers,et al.  Color fidelity of chromatic distributions by triad illuminant comparison , 2011, 2011 IEEE 10th IVMSP Workshop: Perception and Visual Signal Analysis.

[15]  D H Brainard,et al.  Bayesian color constancy. , 1997, Journal of the Optical Society of America. A, Optics, image science, and vision.

[16]  K. Gegenfurtner,et al.  Effects of spatial and temporal context on color categories and color constancy. , 2007, Journal of vision.

[17]  D. Ruderman,et al.  Statistics of cone responses to natural images: implications for visual coding , 1998 .

[18]  Jürgen Golz The role of chromatic scene statistics in color constancy: spatial integration. , 2008, Journal of vision.

[19]  Peter B. Delahunt,et al.  Does human color constancy incorporate the statistical regularity of natural daylight? , 2004, Journal of vision.

[20]  A. Bovik,et al.  A universal image quality index , 2002, IEEE Signal Processing Letters.

[21]  Jeroen J. M. Granzier,et al.  Can illumination estimates provide the basis for color constancy? , 2009, Journal of vision.

[22]  S. D. Hordley,et al.  Reevaluation of color constancy algorithm performance. , 2006, Journal of the Optical Society of America. A, Optics, image science, and vision.

[23]  Theo Gevers,et al.  Comparing objective and subjective error measures for color constancy , 2008, CGIV/MCS.

[24]  D. Brainard,et al.  Color constancy in the nearly natural image. 2. Achromatic loci. , 1998, Journal of the Optical Society of America. A, Optics, image science, and vision.

[25]  Donald I. A. MacLeod,et al.  Influence of scene statistics on colour constancy , 2002, Nature.

[26]  Theo Gevers,et al.  Perceptual analysis of distance measures for color constancy algorithms. , 2009, Journal of the Optical Society of America. A, Optics, image science, and vision.

[27]  H E Smithson,et al.  Sensory, computational and cognitive components of human colour constancy , 2005, Philosophical Transactions of the Royal Society B: Biological Sciences.

[28]  Gerald Schaefer,et al.  Solving for Colour Constancy using a Constrained Dichromatic Reflection Model , 2001, International Journal of Computer Vision.

[29]  Brian V. Funt,et al.  Is Machine Colour Constancy Good Enough? , 1998, ECCV.

[30]  C. van Trigt,et al.  Smoothest reflectance functions. I. Definition and main results , 1990 .

[31]  Ning Wang,et al.  Edge-Based Color Constancy via Support Vector Regression , 2009, IEICE Trans. Inf. Syst..

[32]  Keijiro Yamamoto,et al.  Toward interdisciplinary cooperation in visualization , 2001 .

[33]  Brian A. Wandell,et al.  A spatial extension of CIELAB for digital color‐image reproduction , 1997 .

[34]  Gary S. Settles,et al.  Full-scale schlieren visualization of supersonic bullet and muzzle blast from firing a .30-06 rifle , 2005, J. Vis..

[35]  Peter B. Delahunt,et al.  Bayesian model of human color constancy. , 2006, Journal of vision.

[36]  Michael J. Swain,et al.  Color indexing , 1991, International Journal of Computer Vision.

[37]  David A. Forsyth,et al.  A novel algorithm for color constancy , 1990, International Journal of Computer Vision.

[38]  L. Maloney,et al.  Color constancy: a method for recovering surface spectral reflectance , 1987 .

[39]  Claus Arnold Surface color perception under different illuminants and surface collections , 2009 .