Description du projet
La perception des couleurs des objets naturels
La perception des couleurs est déterminée par des photorécepteurs dans l’œil qui sont activés par la lumière de différentes longueurs d’onde. Le principal objectif du projet Color3.0 financé par l’UE, consiste à revisiter la perception des couleurs autour de vrais objets réels, en tenant compte des aspects dimensionnels de la couleur comme son intensité, sa teinte et sa saturation. Pour comprendre le mécanisme à l’origine du traitement des couleurs, les chercheurs étudieront les circuits neuronaux impliqués dans la perception des couleurs dans les mondes réels et virtuels. Excepté l’apport de connaissances fondamentales sur le système visuel, les résultats du projet aboutiront à une meilleure reproduction des couleurs ainsi qu’à des systèmes d’éclairage améliorés.
Objectif
There have been tremendous advances in color science. The absorption of photons by three types of photoreceptors is known at the molecular genetic level. Human cone fundamentals are tabled to several decimal places and color opponency is understood at the neural and computational level. Yet, all this knowledge is based on extremely restrictive assumptions with a colored light in the dark (Color 1.0) or flat, matte surfaces in a uniformly colored context (Color 2.0). But which mechanisms mediate perception of colors in the real world– when looking at a field of flowers or searching for a certain product in the supermarket?
Arguably, the most important function of color is the processing of information about objects in scenes. It is the tight link to objects through which color helps us see things quicker and remember them better. This proposal, Color 3.0 is based on an active observer dealing with three-dimensional objects in natural environments. It deals with the dimensions relevant for the main purpose of color perception – intensity, hue and saturation. The goal is to fundamentally rethink color science around real world objects and natural tasks.
We will gain a deep understanding of the circuitry underlying color perception in real and virtual worlds, a Deep Neural Network model of color processing that can be traced through the brain, a new colorimetry based on natural object colors rather than flat, matte patches of light, and last but not least a better measure for luminous intensity that can deal with objects of different color. This could lead to a revision of how we study the early visual system, better color reproduction and better lighting systems. Our use of real-time raytracing in VR could cause a paradigm shift in vision science, away from a passively viewing observer pushing buttons, towards an active observer situated in a virtual world and performing a natural task.
Champ scientifique
- engineering and technologymaterials engineeringcolors
- natural sciencesphysical sciencesopticsspectroscopyabsorption spectroscopy
- natural sciencesphysical sciencestheoretical physicsparticle physicsphotons
- natural sciencescomputer and information sciencesartificial intelligencecomputational intelligence
Mots‑clés
Programme(s)
Thème(s)
Régime de financement
ERC-ADG - Advanced GrantInstitution d’accueil
35390 Giessen
Allemagne