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Autores principales: Yang, Kai-Fu, Xing, Dajun, Li, Yong-Jie
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2410.08823
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author Yang, Kai-Fu
Xing, Dajun
Li, Yong-Jie
author_facet Yang, Kai-Fu
Xing, Dajun
Li, Yong-Jie
contents It is still challenging for computer vision to imitate human color perception, e.g., color constancy, which is a fundamental perceptual ability in humans to perceive, interpret and interact with their surroundings. Among others, the anchoring theory provides impressive insights for human lightness perception, yet the specific anchoring rules underlying color constancy have remained contentious for decades. In this work, we introduced a novel computational theory - gray-anchoring (GA) theory - to explain how the early stage of visual system contributes to color constancy and demonstrate how our GA rule applies to the chromatic domain by identifying gray surfaces within complex scenes. Furthermore, we also demonstrate the potential neural implementation of gray-anchoring by quantitatively analyzing the computational flows of concentric double-opponent (DO) cells in V1. The simulational results show that the concentric DO cells have the ability to identify gray surfaces within color-biased scenes and these gray surfaces can then be used by the higher-level cortices to easily estimate the illuminant. This finding offers not only a clear functional explanation of the concentric DO receptive fields of this cell type in the visual system but also an effective and efficient solution to computational color constancy for computer vision.
format Preprint
id arxiv_https___arxiv_org_abs_2410_08823
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Gray Anchoring: a New Computational Theory for Biological Color Constancy
Yang, Kai-Fu
Xing, Dajun
Li, Yong-Jie
Neurons and Cognition
It is still challenging for computer vision to imitate human color perception, e.g., color constancy, which is a fundamental perceptual ability in humans to perceive, interpret and interact with their surroundings. Among others, the anchoring theory provides impressive insights for human lightness perception, yet the specific anchoring rules underlying color constancy have remained contentious for decades. In this work, we introduced a novel computational theory - gray-anchoring (GA) theory - to explain how the early stage of visual system contributes to color constancy and demonstrate how our GA rule applies to the chromatic domain by identifying gray surfaces within complex scenes. Furthermore, we also demonstrate the potential neural implementation of gray-anchoring by quantitatively analyzing the computational flows of concentric double-opponent (DO) cells in V1. The simulational results show that the concentric DO cells have the ability to identify gray surfaces within color-biased scenes and these gray surfaces can then be used by the higher-level cortices to easily estimate the illuminant. This finding offers not only a clear functional explanation of the concentric DO receptive fields of this cell type in the visual system but also an effective and efficient solution to computational color constancy for computer vision.
title Gray Anchoring: a New Computational Theory for Biological Color Constancy
topic Neurons and Cognition
url https://arxiv.org/abs/2410.08823