# A Unified Theory of Early Visual Representations from Retina to Cortex   through Anatomically Constrained Deep CNNs

**Authors:** Jack Lindsey, Samuel A. Ocko, Surya Ganguli, Stephane Deny

arXiv: 1901.00945 · 2019-01-07

## TL;DR

This paper uses anatomically constrained deep CNNs to unify the understanding of early visual representations from retina to cortex, explaining differences as a consequence of neural resource constraints.

## Contribution

It introduces a unified model showing how retinal and cortical representations emerge from resource constraints, reconciling different views of retinal function.

## Key findings

- Retinal output acts as nonlinear, lossy feature detectors in simple networks.
- Cortical representations are linear and faithful encodings in complex networks.
- Predictions about nonlinear computations in small vertebrate retinas and linear encoding in primates.

## Abstract

The visual system is hierarchically organized to process visual information in successive stages. Neural representations vary drastically across the first stages of visual processing: at the output of the retina, ganglion cell receptive fields (RFs) exhibit a clear antagonistic center-surround structure, whereas in the primary visual cortex, typical RFs are sharply tuned to a precise orientation. There is currently no unified theory explaining these differences in representations across layers. Here, using a deep convolutional neural network trained on image recognition as a model of the visual system, we show that such differences in representation can emerge as a direct consequence of different neural resource constraints on the retinal and cortical networks, and we find a single model from which both geometries spontaneously emerge at the appropriate stages of visual processing. The key constraint is a reduced number of neurons at the retinal output, consistent with the anatomy of the optic nerve as a stringent bottleneck. Second, we find that, for simple cortical networks, visual representations at the retinal output emerge as nonlinear and lossy feature detectors, whereas they emerge as linear and faithful encoders of the visual scene for more complex cortices. This result predicts that the retinas of small vertebrates should perform sophisticated nonlinear computations, extracting features directly relevant to behavior, whereas retinas of large animals such as primates should mostly encode the visual scene linearly and respond to a much broader range of stimuli. These predictions could reconcile the two seemingly incompatible views of the retina as either performing feature extraction or efficient coding of natural scenes, by suggesting that all vertebrates lie on a spectrum between these two objectives, depending on the degree of neural resources allocated to their visual system.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1901.00945/full.md

## Figures

11 figures with captions in the complete paper: https://tomesphere.com/paper/1901.00945/full.md

## References

39 references — full list in the complete paper: https://tomesphere.com/paper/1901.00945/full.md

---
Source: https://tomesphere.com/paper/1901.00945