Parallel detection of violations of color constancy

David H. Foster; Sérgio M C Nascimento; Kinjiro Amano; Larry Arend; Karina J. Linnell; Juan Luis Nieves; Sabrina Plet; Jeffrey S. Foster

doi:10.1073/pnas.141505198

Parallel detection of violations of color constancy

David H. Foster, Sérgio M C Nascimento, Kinjiro Amano, Larry Arend, Karina J. Linnell, Juan Luis Nieves, Sabrina Plet, Jeffrey S. Foster

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Abstract

The perceived colors of reflecting surfaces generally remain stable despite changes in the spectrum of the illuminating light. This color constancy can be measured operationally by asking observers to distinguish illuminant changes on a scene from changes in the reflecting properties of the surfaces comprising it. It is shown here that during fast illuminant changes, simultaneous changes in spectral reflectance of one or more surfaces in an array of other surfaces can be readily detected almost independent of the numbers of surfaces, suggesting a preattentive, spatially parallel process. This process, which is perfect over a spatial window delimited by the anatomical fovea, may form an early input to a multistage analysis of surface color, providing the visual system with information about a rapidly changing world in advance of the generation of a more elaborate and stable perceptual representation.

Original language	English
Pages (from-to)	8151-8156
Number of pages	5
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	98
Issue number	14
DOIs	https://doi.org/10.1073/pnas.141505198
Publication status	Published - 2001

Keywords

Cone-excitation ratios
Parallel processing
Surface color
Transient chromatic signals

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POST-PEER-REVIEW-NON-PUBLISHERS.PDFAccepted author manuscript, 107 KB

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title = "Parallel detection of violations of color constancy",

abstract = "The perceived colors of reflecting surfaces generally remain stable despite changes in the spectrum of the illuminating light. This color constancy can be measured operationally by asking observers to distinguish illuminant changes on a scene from changes in the reflecting properties of the surfaces comprising it. It is shown here that during fast illuminant changes, simultaneous changes in spectral reflectance of one or more surfaces in an array of other surfaces can be readily detected almost independent of the numbers of surfaces, suggesting a preattentive, spatially parallel process. This process, which is perfect over a spatial window delimited by the anatomical fovea, may form an early input to a multistage analysis of surface color, providing the visual system with information about a rapidly changing world in advance of the generation of a more elaborate and stable perceptual representation.",

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T1 - Parallel detection of violations of color constancy

AU - Foster, David H.

AU - Nascimento, Sérgio M C

AU - Amano, Kinjiro

AU - Arend, Larry

AU - Linnell, Karina J.

AU - Nieves, Juan Luis

AU - Plet, Sabrina

AU - Foster, Jeffrey S.

PY - 2001

Y1 - 2001

N2 - The perceived colors of reflecting surfaces generally remain stable despite changes in the spectrum of the illuminating light. This color constancy can be measured operationally by asking observers to distinguish illuminant changes on a scene from changes in the reflecting properties of the surfaces comprising it. It is shown here that during fast illuminant changes, simultaneous changes in spectral reflectance of one or more surfaces in an array of other surfaces can be readily detected almost independent of the numbers of surfaces, suggesting a preattentive, spatially parallel process. This process, which is perfect over a spatial window delimited by the anatomical fovea, may form an early input to a multistage analysis of surface color, providing the visual system with information about a rapidly changing world in advance of the generation of a more elaborate and stable perceptual representation.

AB - The perceived colors of reflecting surfaces generally remain stable despite changes in the spectrum of the illuminating light. This color constancy can be measured operationally by asking observers to distinguish illuminant changes on a scene from changes in the reflecting properties of the surfaces comprising it. It is shown here that during fast illuminant changes, simultaneous changes in spectral reflectance of one or more surfaces in an array of other surfaces can be readily detected almost independent of the numbers of surfaces, suggesting a preattentive, spatially parallel process. This process, which is perfect over a spatial window delimited by the anatomical fovea, may form an early input to a multistage analysis of surface color, providing the visual system with information about a rapidly changing world in advance of the generation of a more elaborate and stable perceptual representation.

KW - Cone-excitation ratios

KW - Parallel processing

KW - Surface color

KW - Transient chromatic signals

U2 - 10.1073/pnas.141505198

DO - 10.1073/pnas.141505198

M3 - Article

SN - 0027-8424

VL - 98

SP - 8151

EP - 8156

JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

IS - 14

ER -

Parallel detection of violations of color constancy

Abstract

Keywords

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