A Computational Framework for Modeling Emergence of Color Vision in the Human Brain

Atsunobu Kotani, Ren Ng
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Abstract

It is a mystery how the brain decodes color vision purely from the optic nerve signals it receives, with a core inferential challenge being how it disentangles internal perception with the correct color dimensionality from the unknown encoding properties of the eye. In this paper, we introduce a computational framework for modeling this emergence of human color vision by simulating both the eye and the cortex. Existing research often overlooks how the cortex develops color vision or represents color space internally, assuming that the color dimensionality is known a priori; however, we argue that the visual cortex has the capability and the challenge of inferring the color dimensionality purely from fluctuations in the optic nerve signals. To validate our theory, we introduce a simulation engine for biological eyes based on established vision science and generate optic nerve signals resulting from looking at natural images. Further, we propose a model of cortical learning based on self-supervised principle and show that this model naturally learns to generate color vision by disentangling retinal invariants from the sensory signals. When the retina contains N types of color photoreceptors, our simulation shows that N-dimensional color vision naturally emerges, verified through formal colorimetry. Using this framework, we also present the first simulation work that successfully boosts the color dimensionality, as observed in gene therapy on squirrel monkeys, and demonstrates the possibility of enhancing human color vision from 3D to 4D.
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模拟人脑色觉形成的计算框架
大脑如何纯粹从接收到的视觉信号中解码颜色视觉是一个谜,其核心推论挑战是如何从眼睛未知的编码特性中分离出具有正确颜色维度的内部感知。在本文中,我们引入了一个计算框架,通过模拟眼睛和大脑皮层来模拟人类色彩视觉的出现。现有的研究往往忽略了大脑皮层是如何发展色彩视觉或在内部表示色彩空间的,并假设色彩维度是先验已知的;然而,我们认为视觉皮层有能力也有挑战纯粹从视神经信号的波动中推断色彩维度。为了验证我们的理论,我们引入了一个基于视觉科学的生物眼睛模拟引擎,并生成了观看自然图像时产生的视神经信号。此外,我们还提出了一个基于自我监督原理的皮层学习模型,并证明该模型通过从感觉信号中分离视网膜不变因素,自然地学习生成彩色视觉。当视网膜包含 N 种颜色光感受器时,我们的模拟结果表明,N 维色彩视觉会自然产生,并通过正式的色彩测量得到验证。利用这一框架,我们还首次展示了在松鼠猴基因治疗中观察到的成功提升色彩维度的模拟工作,并证明了将人类色彩视觉从三维提升到四维的可能性。
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