Abstract
Filling-in at the blind spot is a perceptual phenomenon in which the visual system fills the informational void, which arises due to the absence of retinal input corresponding to the optic disc, with surrounding visual attributes. It is known that during filling-in, nonlinear neural responses are observed in the early visual area that correlates with the perception, but the knowledge of underlying neural mechanism for filling-in at the blind spot is far from complete. In this work, we attempted to present a fresh perspective on the computational mechanism of filling-in process in the framework of hierarchical predictive coding, which provides a functional explanation for a range of neural responses in the cortex. We simulated a three-level hierarchical network and observe its response while stimulating the network with different bar stimulus across the blind spot. We find that the predictive-estimator neurons that represent blind spot in primary visual cortex exhibit elevated non-linear response when the bar stimulated both sides of the blind spot. Using generative model, we also show that these responses represent the filling-in completion. All these results are consistent with the finding of psychophysical and physiological studies. In this study, we also demonstrate that the tolerance in filling-in qualitatively matches with the experimental findings related to non-aligned bars. We discuss this phenomenon in the predictive coding paradigm and show that all our results could be explained by taking into account the efficient coding of natural images along with feedback and feed-forward connections that allow priors and predictions to co-evolve to arrive at the best prediction. These results suggest that the filling-in process could be a manifestation of the general computational principle of hierarchical predictive coding of natural images.
Highlights
Filling-in at the blind spot is one of the examples of how brain interpolates the informational void due to the deficit of visual input from the retina
To ascertain whether the computational mechanism of hierarchical predictive coding (HPC) could account for filling-in completion across the blind spot, we conducted a pair of experiments by stimulating the trained HPC model network with bar stimuli
The blind spot was emulated in the network by removing feed-forward connection, whereas, the training was performed on a network by keeping feed-forward connection intact
Summary
Filling-in at the blind spot is one of the examples of how brain interpolates the informational void due to the deficit of visual input from the retina. The concealed visual field is known as the blind spot. Predictive Coding and the Filling-In at the Blind Spot [1]. This completion is known as perceptual filling-in or filling-in. In addition to the blind spot, filling-in occurs in other visual input deficit conditions, e.g. filling-in at the artificial and natural retinal scotoma [2, 3]. In addition to the deficit of input, filling-in occurs in visual illusions such as Neon color spreading, Craik-O’Brien-Cornsweet illusion, Kanizsa shapes, etc. In addition to the deficit of input, filling-in occurs in visual illusions such as Neon color spreading, Craik-O’Brien-Cornsweet illusion, Kanizsa shapes, etc. and steady fixation condition like Troxler effect (for review see [4])
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