Matching Color Images : The Impact of Axial Chromatic Aberration

We show how to compute and to use the wavelength-dependent optical transfer function (OTF) to create color matches between spatially patterned images. We model the human OTF as a defocused optical system with a circular aperture. In our model, the defocus arises from axial chromatic aberration and wavelength-independent aberrations. From the computed OTF, it is apparent that high spatial-frequency components of the image can play little role in contrast and color appearance, and that in the spatial-frequency range from 5-20 cpd, the visual system is dichromatic because there is no contrast in the short-wavelength receptor signal. We show how to use the wavelength-dependent OTF to match color images across displays by setting matches in corresponding spatial-frequency bands. Because chromatic aberration so affects the OTF, this new procedure is a significant improvement over the conventional procedure of setting matches point by point.

[1]  D. Flitcroft The interactions between chromatic aberration, defocus and stimulus chromaticity: Implications for visual physiology and colorimetry , 1989, Vision Research.

[2]  M. Campbell,et al.  The optical transverse chromatic aberration on the fovea of the human eye , 1990, Vision Research.

[3]  D. Baylor,et al.  Spectral sensitivity of human cone photoreceptors , 1987, Nature.

[4]  J. Goodman Introduction to Fourier optics , 1969 .

[5]  D. Brainard,et al.  Double-pass and interferometric measures of the optical quality of the eye. , 1994, Journal of the Optical Society of America. A, Optics, image science, and vision.

[6]  J. Pokorny,et al.  Spectral sensitivity of the foveal cone photopigments between 400 and 500 nm , 1975, Vision Research.

[7]  David H. Brainard,et al.  Calibration of a computer controlled color monitor , 1989 .

[8]  A. van Meeteren,et al.  Calculations on the Optical Modulation Transfer Function of the Human Eye for White Light , 1974 .

[9]  G E Legge,et al.  Tolerance to visual defocus. , 1987, Journal of the Optical Society of America. A, Optics and image science.

[10]  J. M. Foley,et al.  Contrast detection and near-threshold discrimination in human vision , 1981, Vision Research.

[11]  G. Wald,et al.  The change in refractive power of the human eye in dim and bright light. , 1947, Journal of the Optical Society of America.

[12]  G. Wyszecki,et al.  Axial chromatic aberration of the human eye. , 1957, Journal of the Optical Society of America.

[13]  H. H. Hopkins The frequency response of a defocused optical system , 1955, Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences.

[14]  L Levi,et al.  Tables of the modulation transfer function of a defocused perfect lens. , 1968, Applied optics.

[15]  A. Bradley,et al.  The chromatic eye: a new reduced-eye model of ocular chromatic aberration in humans. , 1992, Applied optics.

[16]  Brian A. Wandell,et al.  The Foundations of Color Measurement and Color Perception , 1991 .

[17]  David H. Brainard,et al.  The Cost of Trichromacy for Spatial Vision , 1991 .

[18]  B. Wandell,et al.  Appearance of colored patterns: pattern-color separability. , 1993, Journal of the Optical Society of America. A, Optics, image science, and vision.

[19]  D. Baylor,et al.  Spectral sensitivity of cones of the monkey Macaca fascicularis. , 1987, The Journal of physiology.

[20]  J. Cohen,et al.  Color Science: Concepts and Methods, Quantitative Data and Formulas , 1968 .

[21]  London,et al.  Form and Space Vision , 1972 .