Abstract
Research at the intersection of computer vision and neuroscience has revealed hierarchical correspondence between layers of deep convolutional neural networks (DCNNs) and cascade of regions along human ventral visual cortex. Recently, studies have uncovered emergence of human interpretable concepts within DCNNs layers trained to identify visual objects and scenes. Here, we asked whether an artificial neural network (with convolutional structure) trained for visual categorization would demonstrate spatial correspondences with human brain regions showing central/peripheral biases. Using representational similarity analysis, we compared activations of convolutional layers of a DCNN trained for object and scene categorization with neural representations in human brain visual regions. Results reveal a brain-like topographical organization in the layers of the DCNN, such that activations of layer-units with central-bias were associated with brain regions with foveal tendencies (e.g. fusiform gyrus), and activations of layer-units with selectivity for image backgrounds were associated with cortical regions showing peripheral preference (e.g. parahippocampal cortex). The emergence of a categorical topographical correspondence between DCNNs and brain regions suggests these models are a good approximation of the perceptual representation generated by biological neural networks.
Highlights
Cortical regions along the ventral visual stream of the human brain have been shown to preferentially activate to specific image categories[1]
Here we show that model units with central selectivity show stronger representational similarity to visual brain regions with a strong central-bias, while model units with selectivity for image background are highly correlated with brain regions with peripheral bias (e.g. parahippocampal cortex (PHC))
Hierarchical correspondences have been established between primate ventral visual pathway and layers of DCNNs19,22,23
Summary
Cortical regions along the ventral visual stream of the human brain (extending from occipital to temporal lobe) have been shown to preferentially activate to specific image categories[1]. We compared the representations of units in a deep neural network trained on both object and scene categorization[34] (Hybrid-CNN) with representations from several category-selective areas of the visual hierarchy in the human brain. Given that this DCNN is trained on natural images representing the statistical distribution of visual features in the world, with a bias during learning similar to human visual experience (i.e. most faces are image-centered), we would expect activations of spatial selective nodes in DCNNs demonstrate category-specific topographical correspondences with human brain visual regions.
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