Abstract
While vision evokes a dense network of feedforward and feedback neural processes in the brain, visual processes are primarily modeled with feedforward hierarchical neural networks, leaving the computational role of feedback processes poorly understood. Here, we developed a generative autoencoder neural network model and adversarially trained it on a categorically diverse data set of images. We hypothesized that the feedback processes in the ventral visual pathway can be represented by reconstruction of the visual information performed by the generative model. We compared representational similarity of the activity patterns in the proposed model with temporal (magnetoencephalography) and spatial (functional magnetic resonance imaging) visual brain responses. The proposed generative model identified two segregated neural dynamics in the visual brain. A temporal hierarchy of processes transforming low level visual information into high level semantics in the feedforward sweep, and a temporally later dynamics of inverse processes reconstructing low level visual information from a high level latent representation in the feedback sweep. Our results append to previous studies on neural feedback processes by presenting a new insight into the algorithmic function and the information carried by the feedback processes in the ventral visual pathway.
Highlights
In just a couple of hundred milliseconds, our brain interprets the visual scene around us [1,2,3,4,5], identifies faces [6, 7], recognizes objects [8,9,10,11,12,13], and localizes them [14,15,16,17,18]
It has been shown that the ventral visual cortex consists of a dense network of regions with feedforward and feedback connections
The feedforward path processes visual inputs along a hierarchy of cortical areas that starts in early visual cortex and ends in inferior temporal cortex
Summary
In just a couple of hundred milliseconds, our brain interprets the visual scene around us [1,2,3,4,5], identifies faces [6, 7], recognizes objects [8,9,10,11,12,13], and localizes them [14,15,16,17,18]. Decades of cognitive neuroscience research have demonstrated that the brain accomplishes these complicated tasks through a cascade of hierarchical processes in the ventral visual stream starting in the early visual cortex (EVC) and culminating in the inferior temporal (IT) cortex. Variable timing of neural responses to visual stimuli beyond 200ms has been frequently associated with accumulation of sensory evidence through recurrent processes in the visual brain. The precise computational role of neural recurrent/feedback processes remains poorly understood at the system level. The algorithmic function of feedback processes and the type of information sent back along the visual hierarchy is still unknown
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