Unraveling the complexity of rat object vision requires a full convolutional network and beyond.

IF 6.7 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Patterns Pub Date : 2025-01-17 eCollection Date: 2025-02-14 DOI:10.1016/j.patter.2024.101149

Paolo Muratore, Alireza Alemi, Davide Zoccolan

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Abstract

Despite their prominence as model systems of visual functions, it remains unclear whether rodents are capable of truly advanced processing of visual information. Here, we used a convolutional neural network (CNN) to measure the computational complexity required to account for rat object vision. We found that rat ability to discriminate objects despite scaling, translation, and rotation was well accounted for by the CNN mid-level layers. However, the tolerance displayed by rats to more severe image manipulations (occlusion and reduction of objects to outlines) was achieved by the network only in the final layers. Moreover, rats deployed perceptual strategies that were more invariant than those of the CNN, as they more consistently relied on the same set of diagnostic features across transformations. These results reveal an unexpected level of sophistication of rat object vision, while reinforcing the intuition that CNNs learn solutions that only marginally match those of biological visual systems.

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解开老鼠物体视觉的复杂性需要一个完整的卷积网络，甚至更多。

尽管啮齿类动物作为视觉功能模型系统的突出地位，但它们是否能够真正高级地处理视觉信息仍不清楚。在这里，我们使用卷积神经网络（CNN）来衡量考虑大鼠物体视觉所需的计算复杂性。我们发现，尽管缩放、平移和旋转，大鼠区分物体的能力很好地解释了CNN中间层。然而，大鼠对更严重的图像处理（遮挡和减少物体到轮廓）的容忍度仅在最后几层由网络实现。此外，大鼠部署的感知策略比CNN的更不变，因为它们在转换过程中更一致地依赖于同一组诊断特征。这些结果揭示了老鼠物体视觉的一个意想不到的复杂程度，同时强化了cnn学习的解决方案只与生物视觉系统的解决方案略微匹配的直觉。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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