Return to search

Neural dynamics of invariant object recognition: relative disparity, binocular fusion, and predictive eye movements

How does the visual cortex learn invariant object categories as an observer scans
a depthful scene? Two neural processes that contribute to this ability are modeled in this
thesis.

The first model clarifies how an object is represented in depth. Cortical area V1
computes absolute disparity, which is the horizontal difference in retinal location of an
image in the left and right foveas. Many cells in cortical area V2 compute relative
disparity, which is the difference in absolute disparity of two visible features. Relative,
but not absolute, disparity is unaffected by the distance of visual stimuli from an
observer, and by vergence eye movements. A laminar cortical model of V2 that includes
shunting lateral inhibition of disparity-sensitive layer 4 cells causes a peak shift in cell
responses that transforms absolute disparity from V1 into relative disparity in V2.

The second model simulates how the brain maintains stable percepts of a 3D
scene during binocular movements. The visual cortex initiates the formation of a 3D boundary and surface representation by binocularly fusing corresponding features from
the left and right retinotopic images. However, after each saccadic eye movement, every
scenic feature projects to a different combination of retinal positions than before the
saccade. Yet the 3D representation, resulting from the prior fusion, is stable through the
post-saccadic re-fusion. One key to stability is predictive remapping: the system
anticipates the new retinal positions of features entailed by eye movements by using gain
fields that are updated by eye movement commands. The 3D ARTSCAN model
developed here simulates how perceptual, attentional, and cognitive interactions across
different brain regions within the What and Where visual processing streams interact to
coordinate predictive remapping, stable 3D boundary and surface perception, spatial
attention, and the learning of object categories that are invariant to changes in an object's
retinal projections. Such invariant learning helps the system to avoid treating each new
view of the same object as a distinct object to be learned. The thesis hereby shows how a
process that enables invariant object category learning can be extended to also enable
stable 3D scene perception.

Identiferoai:union.ndltd.org:bu.edu/oai:open.bu.edu:2144/15402
Date12 March 2016
CreatorsSrinivasan, Karthik
Source SetsBoston University
Languageen_US
Detected LanguageEnglish
TypeThesis/Dissertation

Page generated in 0.0012 seconds