Gabor Patches are presented through Gaussian windows

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Transcript Gabor Patches are presented through Gaussian windows

• Studies have shown that neurons in the primary visual
cortex can be manipulated under an appropriate set of
stimulus conditions
• The result of correct conditions is the Gabor patch which is
considered a common building block when working with
visual stimuli
• The reason they work is because “they
have characteristics that match the
receptive field properties of neurons
in primary visual cortex”
• It consists of a visual
representation of a sine
wave grating seen through a
Gaussian window
Definition: “An image in which light intensity alternates between
its brightest and darkest values according to a sine function” It
flows smoothly; no abrupt edges.
o The grating of the Sine wave is sampled through the
array of receptors at the back of the retina
o Perception of Sine wave grating depend on spacing.
 If the receptors are spaced apart so that the
whitest and blackest parts of the grating fall on
separate cones, the grating can be made out.
 If too tightly packed, the stimulus lands on the
same cone and grating can’t be made out.
 Aliasing – misperceiving cycles to be longer than
they actually are
-The sharp edge eliminator!
-Gaussian window softens the edges so the change at the edges is not as
abrupt so that the waves are detected instead of the hard edges formed
around the waves.
-Gabor Patches are presented through Gaussian windows
Measured in cycle/degree
Smaller cycle results in a higher spatial frequency and vice
versa
The contrast simply refers to the differences in intensity
throughout the different portions of the patch.
High contrast patches have light regions show up in white and
dark regions as black. In low contrast light regions are light grey
and dark regions are dark grey.
-the relative position of a sine wave within the receptive field
-position shifts between 0-90-180-270 degrees
-response levels of ganglion cells are dependent upon the phase of the
grating
Ex. On-Center Ganglion Cells (w/ ideal spatial frequency)
-0° yields positive response
-90° yields no response
-180° yields negative response
-270° yields no response
-other cells respond to different phases, filling the “gaps”
One example of an application of the Gabor Patch is the RevitalVision
patient learning program.
The RevitalVision patient learning computer program aids patients in
through presenting visual stimuli such as the Gabor Patch. Patients can
improve their own vision through observing the differences in visual
stimuli presented by the Gabor Patch
In modern rehabilitation an application of this would be for people who
have had a stroke in the past. Since their visual system might be affected,
therapists can use this program to improve and rehabilitate patient’s
vision. This is accomplished through exposure to the Gabor Patch so that
the patients’ sensitivity to different frequencies of light may be
improved.
Source:
http://www.revitalvision.com/Doctors/ScientificBackground/