人类视觉皮层中的通用无标度表征

Raj Magesh Gauthaman, Brice Ménard, Michael F. Bonner
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引用次数: 0

摘要

人类视觉皮层是如何编码感觉信息的?为了解决这个问题,我们探索了神经表征的协方差结构。我们对 "自然场景数据集 "中多个个体对自然图像的 fMRI 反应进行了交叉分解分析,发现神经表征系统地呈现出幂律协方差谱,其等级超过四个数量级。这种无标度结构出现在视觉层次结构的多个区域,表明视觉皮层中存在通用的编码策略。我们还发现,在旋转之前,这些群体编码的主轴在不同受试者之间存在大量的共享性,这表明存在一种通用的高维表征。这表明,尽管个体在神经解剖学和经验方面存在差异,但人类大脑在学习如何表现自然场景方面具有高度的趋同性。我们进一步证明,频谱方法对于全面描述群体代码至关重要,而且在此过程中,我们揭示了传统方差加权方法无法触及的未知维度的广阔空间。因此,要对神经表征进行全局观察,就必须接受其高维特性,并从统计学角度而不是通过对单个维度的视觉或语义解释来理解它们。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Universal scale-free representations in human visual cortex
How does the human visual cortex encode sensory information? To address this question, we explore the covariance structure of neural representations. We perform a cross-decomposition analysis of fMRI responses to natural images in multiple individuals from the Natural Scenes Dataset and find that neural representations systematically exhibit a power-law covariance spectrum over four orders of magnitude in ranks. This scale-free structure is found in multiple regions along the visual hierarchy, pointing to the existence of a generic encoding strategy in visual cortex. We also show that, up to a rotation, a large ensemble of principal axes of these population codes are shared across subjects, showing the existence of a universal high-dimensional representation. This suggests a high level of convergence in how the human brain learns to represent natural scenes despite individual differences in neuroanatomy and experience. We further demonstrate that a spectral approach is critical for characterizing population codes in their full extent, and in doing so, we reveal a vast space of uncharted dimensions that have been out of reach for conventional variance-weighted methods. A global view of neural representations thus requires embracing their high-dimensional nature and understanding them statistically rather than through visual or semantic interpretation of individual dimensions.
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