Abstract
An influential theory of mammalian vision, known as the efficient coding hypothesis, holds that early stages in the visual cortex attempts to form an efficient coding of ecologically valid stimuli. Although numerous authors have successfully modelled some aspects of early vision mathematically, closer inspection has found substantial discrepancies between the predictions of some of these models and observations of neurons in the visual cortex. In particular analysis of linear-non-linear models of simple-cells using Independent Component Analysis has found a strong bias towards features on the horoptor. In order to investigate the link between the information content of binocular images, mathematical models of complex cells and physiological recordings, we applied Independent Subspace Analysis to binocular image patches in order to learn a set of complex-cell-like models. We found that these complex-cell-like models exhibited a wide range of binocular disparity-discriminability, although only a minority exhibited high binocular discrimination scores. However, in common with the linear-non-linear model case we found that feature detection was limited to the horoptor suggesting that current mathematical models are limited in their ability to explain the functionality of the visual cortex.
Highlights
Binocular disparity detectionMany animals view the world through two eyes
Features in the binocular view are at zero disparity when they appear in the same location within the receptive fields in both views, zero disparities are found on the main diagonal in each plot
As with the ideal detector the strongest responses are found on the main diagonal indicating that the binocular energy model is strongly tuned to detect disparities of zero
Summary
Binocular disparity detectionMany animals view the world through two eyes. two views of the world confer advantages such as a wider field of view, greater visual acuity in areas of overlapping fields of view and a perception of depth from binocular disparities, calculation of a single cyclopean view from two inputs is non-trivial. In order to create a single fused percept, and to estimate binocular disparity, corresponding features in both views must be matched These features can vary in orientation, shape, and size, as well as their locations in the two eyes. The standard model of this process proposes that disparity is determined by cross-correlation of the visual signals from the left and right views [1, 2]. This idea of calculating a local cross-correlation has been linked to the activity of simple and complex cells in the primary visual cortex through the binocular energy model [3, 4]
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