Paper Info
Title
A rotation-equivariant convolutional neural network model of primary visual cortex.
Abstract
Classical models describe primary visual cortex (V1) as a filter bank of orientation-selective linear-nonlinear (LN) or energy models, but these models fail to predict neural responses to natural stimuli accurately. Recent work shows that models based on convolutional neural networks (CNNs) lead to much more accurate predictions, but it remains unclear which features are extracted by V1 neurons beyond orientation selectivity and phase invariance. Here we work towards systematically studying V1 computations by categorizing neurons into groups that perform similar computations. We present a framework to identify common features independent of individual neuronsu0027 orientation selectivity by using a rotation-equivariant convolutional neural network, which automatically extracts every feature at multiple different orientations. We fit this model to responses of a population of 6000 neurons to natural images recorded in mouse primary visual cortex using two-photon imaging. We show that our rotation-equivariant network not only outperforms a regular CNN with the same number of feature maps, but also reveals a number of common features shared by many V1 neurons, which deviate from the typical textbook idea of V1 as a bank of Gabor filters. Our findings are a first step towards a powerful new tool to study the nonlinear computations in V1.
Year
Venue
Field
2018
ICLR
Equivariant map,Pattern recognition,Visual cortex,Convolutional neural network,Computer science,Artificial intelligence
DocType
Volume
Citations 
Journal
abs/1809.10504
0
PageRank 
References 
Authors
0.34
0
10
Name
Order
Citations
PageRank
Alexander S. Ecker160027.06
Fabian H. Sinz214313.38
Emmanouil Froudarakis372.30
Paul G. Fahey401.69
Santiago A. Cadena533.15
Edgar Y. Walker633.83
Erick Cobos701.69
Jacob Reimer801.35
a s tolias98710.70
Matthias Bethge10131682.73