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Literature DB >> 32400553

Effect of cone spectral topography on chromatic detection sensitivity.

Alexandra Neitz, Xiaoyun Jiang, James A Kuchenbecker, Niklas Domdei, Wolf Harmening, Hongyi Yan, Jihyun Yeonan-Kim, Sara S Patterson, Maureen Neitz, Jay Neitz, Daniel R Coates, Ramkumar Sabesan.

Abstract

The spatial and spectral topography of the cone mosaic set the limits for detection and discrimination of chromatic sinewave gratings. Here, we sought to compare the spatial characteristics of mechanisms mediating hue perception against those mediating chromatic detection in individuals with known spectral topography and with optical aberrations removed with adaptive optics. Chromatic detection sensitivity in general exceeded previous measurements and decreased monotonically for increasingly skewed cone spectral compositions. The spatial grain of hue perception was significantly coarser than chromatic detection, consistent with separate neural mechanisms for color vision operating at different spatial scales.

Entities: Chemical Disease Gene Species

Year: 2020 PMID： 32400553 PMCID： PMC7231539 DOI： 10.1364/JOSAA.382384

Source DB: PubMed Journal: J Opt Soc Am A Opt Image Sci Vis ISSN： 1084-7529 Impact factor: 2.129

35 in total

1. Organization of the human trichromatic cone mosaic.

Authors: Heidi Hofer; Joseph Carroll; Jay Neitz; Maureen Neitz; David R Williams
Journal: J Neurosci Date: 2005-10-19 Impact factor: 6.167

2. Statistical distribution of foveal transverse chromatic aberration, pupil centration, and angle psi in a population of young adult eyes.

Authors: M Rynders; B Lidkea; W Chisholm; L N Thibos
Journal: J Opt Soc Am A Opt Image Sci Vis Date: 1995-10 Impact factor: 2.129

3. Eye tracking-based estimation and compensation of chromatic offsets for multi-wavelength retinal microstimulation with foveal cone precision.

Authors: Niklas Domdei; Michael Linden; Jenny L Reiniger; Frank G Holz; Wolf M Harmening
Journal: Biomed Opt Express Date: 2019-07-18 Impact factor: 3.732

Effect of cone spectral topography on chromatic detection sensitivity.

1. Organization of the human trichromatic cone mosaic.

2. Statistical distribution of foveal transverse chromatic aberration, pupil centration, and angle psi in a population of young adult eyes.

3. Eye tracking-based estimation and compensation of chromatic offsets for multi-wavelength retinal microstimulation with foveal cone precision.

4. Calculation of the influence of lateral chromatic aberration on image quality across the visual field.

5. Spatiotemporal chromaticity discrimination.

6. Efficiency in detection of isoluminant and isochromatic interference fringes.

7. The contrast sensitivity of human colour vision to red-green and blue-yellow chromatic gratings.

8. Eye-tracking technology for real-time monitoring of transverse chromatic aberration.

9. Colour pools, brightness pools, assimilation, and the spatial resolving power of the human colour-vision system.

10. Theory and measurement of ocular chromatic aberration.

1. How We See Black and White: The Role of Midget Ganglion Cells.

2. Influence of Stimulus Size on Simultaneous Chromatic Induction.

3. An image reconstruction framework for characterizing initial visual encoding.

4. Temporal filtering of luminance and chromaticity in macaque visual cortex.