Comparing the brain's representation of shape to that of a deep convolutional neural network

International Conference on Bio-inspired Information and Communications Technologies Pub Date : 2016-05-24 DOI:10.4108/EAI.3-12-2015.2262486

Dean A. Pospisil, Anitha Pasupathy, W. Bair

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引用次数: 8

Abstract

Hierarchical neural nets are currently the highest performing general purpose image recognition computer algorithms. Their design is loosely inspired by the neural architecture of the ventral visual pathway in the primate brain, which is believed to underlie the perception of form and the ability to recognize objects. The exact tuning of artificial neural units within an HNN, however, is not prescribed from known biology, but is trained using a performance-based learning algorithm. In evaluating whether HNNs are ripe for further bio-inspired performance improvements, it is of interest to test whether the response properties in the intermediate layers of the HNN approximate those of the ventral visual stream. We therefore characterized units within a popular HNN with a set of visual stimuli that has been employed by neurophysiologists to successfully characterize the shape-tuning properties of neurons in the intermediate visual cortical area V4 of the ventral stream. We found that the tuning and fits of a small but significant number of units in the HNN were strikingly similar to those of some V4 neurons for our simple set of test shapes. There tended to be more such units in the deeper layers of the HNN. We discuss implications of our results to the encoding of curvature in the primate brain and propose ways to further characterize V4-like shape tuning in HNNs.

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将大脑对形状的表征与深度卷积神经网络的表征进行比较

层次神经网络是目前性能最高的通用图像识别计算机算法。他们的设计灵感大致来自灵长类动物大脑中腹侧视觉通路的神经结构，人们认为腹侧视觉通路是感知形状和识别物体能力的基础。然而，HNN中人工神经单元的精确调整并不是由已知的生物学规定的，而是使用基于性能的学习算法进行训练。在评估HNN是否成熟到可以进一步提高生物性能时，测试HNN中间层的响应特性是否与腹侧视觉流的响应特性近似是有意义的。因此，我们用一组视觉刺激来表征流行HNN内的单元，神经生理学家已经利用这些视觉刺激成功地表征了腹侧流中间视觉皮质区V4神经元的形状调节特性。我们发现，对于我们简单的测试形状集，HNN中少量但数量显著的单元的调整和拟合与一些V4神经元的调整和拟合惊人地相似。在HNN的较深层中往往有更多这样的单位。我们讨论了我们的结果对灵长类大脑中曲率编码的影响，并提出了进一步表征HNNs中v4样形状调谐的方法。

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International Conference on Bio-inspired Information and Communications Technologies

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