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A better understanding of the color constancy mechanism in human color vision [7] can be reached through analyses of
photometric data of all illuminants and patches (Mondrians or other visible objects) involved in visual experiments. In
Part I [3] and in [4, 5 and 6] the integration in the human eye of the geometrical-optical imaging hardware and the
diffractive-optical hardware has been described and illustrated (Fig.1). This combined hardware represents the main
topic of the NAMIROS research project (nano- and micro- 3D gratings for optical sensors) [8] promoted and coordinated
by Corrsys 3D Sensors AG. The hardware relevant to (photopic) human color vision can be described as a diffractive or
interference-optical correlator transforming incident light into diffractive-optical RGB data and relating local RGB onto
global RGB data in the near-field behind the 'inverted' human retina. The relative differences at local/global RGB
interference-optical contrasts are available to photoreceptors (cones and rods) only after this optical pre-processing.
N. Lauinger
"New experimental diffractive-optical data on E.Land's Retinex
mechanism in human color vision: Part II", Proc. SPIE 6764, Intelligent Robots and Computer Vision XXV: Algorithms, Techniques, and Active Vision, 67640H (10 September 2007); https://doi.org/10.1117/12.733496
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N. Lauinger, "New experimental diffractive-optical data on E.Land's Retinex mechanism in human color vision: Part II," Proc. SPIE 6764, Intelligent Robots and Computer Vision XXV: Algorithms, Techniques, and Active Vision, 67640H (10 September 2007); https://doi.org/10.1117/12.733496