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Color stimuli perception in presence of light scattering

Published online by Cambridge University Press:  06 September 2006

MARIS OZOLINSH
Affiliation:
University of Latvia, Department of Optometry and Vision Science, Riga, Latvia
MICHÉLE COLOMB
Affiliation:
Laboratoire Régional des Ponts et Chaussées (LRPC) de Clermont-Ferrand, France
GATIS IKAUNIEKS
Affiliation:
University of Latvia, Department of Optometry and Vision Science, Riga, Latvia
VARIS KARITANS
Affiliation:
University of Latvia, Department of Optometry and Vision Science, Riga, Latvia

Abstract

Perception of different color contrast stimuli was studied in the presence of light scattering: in a fog chamber in Clermont-Ferrand and in laboratory conditions where light scattering of similar levels was obtained, using different light scattering eye occluders. Blue (shortest wavelength) light is scattered in fog to the greatest extent, causing deterioration of vision quality especially for the monochromatic blue stimuli. However, for the color stimuli presented on a white background, visual acuity in fog for blue Landolt-C optotypes was higher than for red and green optotypes on the white background. The luminance of color Landolt-C optotypes presented on a LCD screen was chosen corresponding to the blue, green, and red color contributions in achromatic white stimuli (computer digital R, G, or B values for chromatic stimuli equal to RGB values in the achromatic white background) that results in the greatest luminance contrast for the white–blue stimuli, thus advancing the visual acuity for the white-blue stimuli. Besides such blue stimuli on the white background are displayed with a uniform, spatially unmodulated distribution of the screen blue phosphor emission over the entire area of the screen including the stimulus C optotype area. It follows that scattering, which has the greatest effect on the blue component of screen luminance, has the least effect on the perception of white–blue stimuli.

Type
PERCEPTION
Copyright
© 2006 Cambridge University Press

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References

REFERENCES

Anderson, S.J. & Holliday, I.E. (1995). Night driving: Effects of glare from vehicle headlights on motion perception. Ophthalmic and Physiological Optics 15, 545552.Google Scholar
Bueno, J.M., Berrio, E., Ozolinsh, M., & Artal, P. (2004). Degree of polarization as an objective method of estimating scattering, Journal of the Optical Society of America 21, 13161321.Google Scholar
Blatherwick, P. & Hallett, P.E. (1992). The discrimination of blur in peripheral colored borders. Vision Research 32, 17191727.Google Scholar
Bullough, J.D. & Rea, M.S. (2001). Driving in snow: Effect of headlamp color at mesopic and photopic light levels. In Lighting Technology Developments for Vehicles SP-1595, pp. 6775. Warrendale, PA: Society of Automotive Engineers.
Cavallo, V., Colomb, M., & Dore, J. (2001). Distance perception of vehicle rear lights in fog. Human Factors 43, 442452.Google Scholar
Colomb, M. (2002). Les salles de brouillard artificiel. In Brouillard et visibilité routière. Actes des journées scientifiques—LCPC, pp. 2937. Paris: Laboratoire Central des Ponts et Chaussées.
Engel, S.A. & Furmanski, Ch.S. (2001). Selective adaptation to color contrast in human primary visual cortex. The Journal of Neuroscience 21, 39493954.Google Scholar
Lohmann, C.P., Fitzke, F., O'Brart, D., Muir, M.K., Timberlake, G., & Marshall, J. (1993). Corneal light scattering and visual performance in myopic individuals with spectacles, contact lenses, or excimer laser photorefractive keratectomy. American Journal of Ophthalmology 115, 444453.Google Scholar
Mainster, M.A. & Timberlake, G.T. (2003). Why HID headlights bother older drivers. British Journal of Ophthalmology 87, 113117.Google Scholar
Metha, A.B. & Lennie, P. (2001). Transmission of spatial information in S-cone pathways. Visual Neuroscience 18, 961972.Google Scholar
Mizokami, Y., Paras, C., & Webster, M.A. (2004). Chromatic and contrast selectivity in color contrast adaptation. Visual Neuroscience 21, 359363.Google Scholar
Monaci, G., Menegaz, G., Süsstrunk, S., & Knoblauch, K. (2004). Chromatic contrast detection in spatial chromatic noise. Visual Neuroscience 21, 291294.Google Scholar
Nayar, S.K. & Narasimhan, S.G. (1999). Vision in bad weather. Proc. ICCV IEEE Computer Society 2, 820827.Google Scholar
Ozolinsh, M., Lacis, I., Paeglis, R., Sternberg, A., Svanberg, S., Andersson-Engels, S., & Swartling, J. (2002). Electrooptic PLZT ceramics devices for vision science applications. Ferroelectrics 273, 131136.Google Scholar
Ozolinsh, M. & Papelba, G. (2004). Eye cataract simulation using polymer dispersed liquid crystal scattering obstacles. Ferroelectrics 304, 207212.Google Scholar
Pesudovs, K., Hazel, C.A., & Elliott, D.B. (2004). The usefulness of Vistech and FACT contrast sensitivity charts for cataract and refractive surgery outcomes research. British Journal of Ophthalmology 88, 1116.Google Scholar
Plainis, S. & Murray, I.J. (2002). Reaction times as an index of visual conspicuity when driving at night. Ophthalmic and Physiological Optics 22, 409415.Google Scholar
Roorda, A. & Williams, D.R. (1999). The arrangement of the three cone classes in the living human eye. Nature 397, 520522.Google Scholar
Tan, J.C., Spalton, D.J., & Arden, G.B. (1998). Comparison of methods to assess visual impairment from glare and light scattering with posterior capsule opacification. Journal of Cataract Refractive Surgery 24, 16261631.Google Scholar
Walkey, H.C., Barbur, J.L., Harlow, J.A., Hurden, A., Morehead, I.R., & Taylor, J.A.F. (2005). Effective contrast of colored stimuli in the mesopic range: A metric for perceived contrast based on achromatic luminance contrast. Journal of the Optical Society of America 22, 1728.Google Scholar
Willis, A. & Anderson, S.J. (2002). Color and luminance interactions in the visual perception of motion. Proceedings of the Royal Society, London, B 269, 10111016.Google Scholar