The highest luminance anchoring rule in achromatic color perception: some counterexamples and an alternative theory.
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[1] A. Bethe,et al. Handbuch der Normalen und Pathologischen Physiologie , 1925 .
[2] H. Helson. Some Factors and Implications of Color Constancy , 1943 .
[3] H. Wallach. Brightness constancy and the nature of achromatic colors. , 1948, Journal of experimental psychology.
[4] A. L. Diamond,et al. Foveal simultaneous brightness contrast as a function of inducing-and test-field luminances. , 1953, Journal of experimental psychology.
[5] E. G. Heinemann,et al. Simultaneous brightness induction as a function of inducing and test-field luminances. , 1955, Journal of experimental psychology.
[6] A. Kozaki. A FURTHER STUDY IN THE RELATIONSHIP BETWEEN BRIGHTNESS CONSTANCY AND CONTRAST , 1963 .
[7] H. Wallach,et al. The perception of neutral colors. , 1963, Scientific American.
[8] H. Helson,et al. Adaptation-level theory , 1964 .
[9] A. Kozaki. THE EFFECT OF CO-EXISTENT STIMULI OTHER THAN TEST STIMULUS ON BRIGHTNESS CONSTANCY , 1965 .
[10] P. Whittle,et al. The effect of background luminance on the brightness of flashes. , 1969, Vision research.
[11] E. Land,et al. Lightness and retinex theory. , 1971, Journal of the Optical Society of America.
[12] Eric G. Heinemann,et al. Simultaneous Brightness Induction , 1972 .
[13] Berthold K. P. Horn,et al. Determining lightness from an image , 1974, Comput. Graph. Image Process..
[14] B. Brown. Proceedings of the Society of Photo-optical Instrumentation Engineers , 1975 .
[15] M. Sanders. Handbook of Sensory Physiology , 1975 .
[16] Berthold K. P. Horn. Understanding Image Intensities , 1977, Artif. Intell..
[17] E. Land. The retinex theory of color vision. , 1977, Scientific American.
[18] D. G. Albrecht,et al. Spatial frequency selectivity of cells in macaque visual cortex , 1982, Vision Research.
[19] E H Land,et al. Recent advances in retinex theory and some implications for cortical computations: color vision and the natural image. , 1983, Proceedings of the National Academy of Sciences of the United States of America.
[20] A. Gilchrist,et al. The classification and integration of edges as critical to the perception of reflectance and illumination , 1983, Perception & psychophysics.
[21] D. Teller. Linking propositions , 1984, Vision Research.
[22] H. Wilson,et al. Modified line-element theory for spatial-frequency and width discrimination. , 1984, Journal of the Optical Society of America. A, Optics and image science.
[23] S Grossberg,et al. Neural dynamics of brightness perception: Features, boundaries, diffusion, and resonance , 1984, Perception & Psychophysics.
[24] H. Wilson,et al. Spatial-frequency adaptation and grating discrimination: predictions of a line-element model. , 1984, Journal of the Optical Society of America. A, Optics and image science.
[25] J. Daugman. Uncertainty relation for resolution in space, spatial frequency, and orientation optimized by two-dimensional visual cortical filters. , 1985, Journal of the Optical Society of America. A, Optics and image science.
[26] Andrew Blake,et al. Boundary conditions for lightness computation in Mondrian World , 1985, Comput. Vis. Graph. Image Process..
[27] S. Grossberg,et al. Neural dynamics of form perception: boundary completion, illusory figures, and neon color spreading. , 1985, Psychological review.
[28] R Shapley,et al. Contrast and assimilation in the perception of brightness. , 1985, Proceedings of the National Academy of Sciences of the United States of America.
[29] E. Land. Recent advances in retinex theory , 1986, Vision Research.
[30] David S. Brée,et al. Linking Propositions , 1986, COLING.
[31] E H Land,et al. An alternative technique for the computation of the designator in the retinex theory of color vision. , 1986, Proceedings of the National Academy of Sciences of the United States of America.
[32] A Hurlbert,et al. Formal connections between lightness algorithms. , 1986, Journal of the Optical Society of America. A, Optics and image science.
[33] L. Arend,et al. Simultaneous constancy, lightness, and brightness. , 1987, Journal of the Optical Society of America. A, Optics and image science.
[34] A. Gilchrist,et al. Hess and Pretori revisited: Resolution of some old contradictions , 1988, Perception & psychophysics.
[35] S. Grossberg,et al. Neural dynamics of 1-D and 2-D brightness perception: A unified model of classical and recent phenomena , 1988, Perception & psychophysics.
[36] R. Shapley,et al. Brightness induction by local contrast and the spatial dependence of assimilation , 1988, Vision Research.
[37] A. Gilchrist. Lightness contrast and failures of constancy: A common explanation , 1988, Perception & psychophysics.
[38] S. Grossberg,et al. A neural network architecture for preattentive vision , 1989, IEEE Transactions on Biomedical Engineering.
[39] E. Adelson. Perceptual organization and the judgment of brightness. , 1993, Science.
[40] L. Arend,et al. Lightness, brightness, and brightness contrast: 2. Reflectance variation , 1993, Perception & psychophysics.
[41] L. Arend,et al. Lightness, brightness, and brightness contrast: 1. Illuminance variation , 1993, Perception & psychophysics.
[42] N. Bruno. Failures of lightness constancy, edge integration, and local edge enhancement , 1994, Vision Research.
[43] Steven K. Shevell,et al. Brightness contrast from inhomogeneous surrounds , 1996, Vision Research.
[44] Karl Frederick Arrington,et al. Directional Filling-in , 1996, Neural Computation.
[45] Tiziano Agostini,et al. Lightness contrast in CRT and paper-and-illuminant displays , 1996, Perception & psychophysics.
[46] B. Spehar,et al. Induced Effects of Backgrounds and Foregrounds in Three-Dimensional Configurations: The Role of T-Junctions , 1997, Perception.
[47] D. Todorović. Lightness and Junctions , 1997, Perception.
[48] B. Anderson. A Theory of Illusory Lightness and Transparency in Monocular and Binocular Images: The Role of Contour Junctions , 1997, Perception.
[49] D H Brainard,et al. The Psychophysics Toolbox. , 1997, Spatial vision.
[50] M. McCourt,et al. Similar mechanisms underlie simultaneous brightness contrast and grating induction , 1997, Vision Research.
[51] P. Bernardis,et al. Lightness, equivalent backgrounds, and anchoring , 1997, Perception & psychophysics.
[52] D G Pelli,et al. The VideoToolbox software for visual psychophysics: transforming numbers into movies. , 1997, Spatial vision.
[53] M. McCourt,et al. A multiscale spatial filtering account of the White effect, simultaneous brightness contrast and grating induction , 1999, Vision Research.
[54] A. Gilchrist,et al. Relative area and relative luminance combine to anchor surface lightness values , 1999, Perception & psychophysics.
[55] A. Gilchrist,et al. An anchoring theory of lightness perception. , 1999 .
[56] W. D. Ross,et al. Lightness from contrast: A selective integration model , 2000, Perception & psychophysics.
[57] M. Rudd,et al. Darkness filling-in: a neural model of darkness induction , 2001, Vision Research.
[58] M. McCourt,et al. A multiscale spatial filtering account of the Wertheimer–Benary effect and the corrugated Mondrian , 2001, Vision Research.
[59] Heiko Neumann,et al. Visual filling-in for computing perceptual surface properties , 2001, Biological Cybernetics.
[60] P. Bressan,et al. Simultaneous Lightness Contrast with Double Increments , 2001, Perception.
[61] Michael E. Rudd,et al. Lightness computation by a neural filling-in mechanism , 2001, IS&T/SPIE Electronic Imaging.
[62] Blocking of achromatic color induction signals by borders of different contrast polarities , 2002 .
[63] Alexander D Logvinenko. Articulation in the Context of Edge Classification , 2002, Perception.
[64] A quantitative model of achromatic color induction based on separate lightness and darkness filling-in processes , 2002 .
[65] M. Rudd. Reflectance-to-color mappings depend critically on spatial context , 2003, Behavioral and Brain Sciences.
[66] Michael E. Rudd,et al. Progress on a computational model of achromatic color processing , 2003, IS&T/SPIE Electronic Imaging.
[67] L. Harris,et al. Levels of Perception , 2013, Springer New York.
[68] M. McCourt,et al. A Multiscale Spatial Filtering Account of Brightness Phenomena , 2003 .
[69] M. McCourt,et al. A unified theory of brightness contrast and assimilation incorporating oriented multiscale spatial filtering and contrast normalization , 2004, Vision Research.
[70] Dorin Popa,et al. A Theory of the Neural Processes Underlying Edge Integration in Human Lightness Perception , 2004 .
[71] M. Rudd,et al. Quantitative properties of achromatic color induction: An edge integration analysis , 2004, Vision Research.