The ability to perceive the sharpness of abject boundaries is central to the quality of vision yet very little is know about the underlying neural mechanisms. The broad long-term objective of this research proposal is to reach a more profound understanding of neural mechanisms that determine the perceived form of moving objects in human vision. Under normal viewing conditions, moving objects appear much less blurred than what one would predict from the long duration of visual persistence. This phenomenon is known as motion deblurring. A specific goal of this research is to study the mechanisms underlying motion deblurring and their implications for the perceived form of moving objects. The approach will combine computational and psychophysical methods to test the mechanisms proposed in a neural network model of retino-cortical dynamics. The model leads to the following specific hypotheses: Hypothesis 1 (spatio-temporal profiles): (i) The metacontrast masking function for spatially localized stimuli is oscillatory; (ii) these oscillations are a by-product of the retino-cortical system that occur when it is driven externally by high luminance inputs or internally by focused-arousal/attention; and (iii) the smooth character of the """"""""classical"""""""" metacontrast function-extensively reported in the literature-results from spatio-temporal averaging in the post-retinal network. Hypothesis 2 (spatial extent of motion blur): The primary mechanism that determines the length of perceived smear for moving targets is an inhibition from transient cells to sustained cells. Hypothesis 3 (perceived form of motion blur): The brightness profile produced by the retino-cortical dynamics model in response to an isolated moving target will match the psychophysically measured brightness profile of the phenomenon known as """"""""Charpentier's bands.""""""""

Agency
National Institute of Health (NIH)
Institute
National Institute of Mental Health (NIMH)
Type
Research Project (R01)
Project #
5R01MH049892-07
Application #
6392034
Study Section
Special Emphasis Panel (ZRG1-IFCN-8 (01))
Program Officer
Glanzman, Dennis L
Project Start
1992-09-01
Project End
2005-05-31
Budget Start
2001-06-01
Budget End
2002-05-31
Support Year
7
Fiscal Year
2001
Total Cost
$147,500
Indirect Cost
Name
University of Houston
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
800771594
City
Houston
State
TX
Country
United States
Zip Code
77204
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Tong, Jianliang; Ramamurthy, Mahalakshmi; Patel, Saumil S et al. (2009) The temporal impulse response function during smooth pursuit. Vision Res 49:2835-42
Bedell, Harold E; Ramamurthy, Mahalakshmi; Patel, Saumil S et al. (2008) The temporal impulse response function in infantile nystagmus. Vision Res 48:1575-83
Breitmeyer, Bruno G; Koc, Alpay; Ogmen, Haluk et al. (2008) Functional hierarchies of nonconscious visual processing. Vision Res 48:1509-13
Chung, Susana T L; Patel, Saumil S; Bedell, Harold E et al. (2007) Spatial and temporal properties of the illusory motion-induced position shift for drifting stimuli. Vision Res 47:231-43
Breitmeyer, Bruno G; Ro, Tony; Ogmen, Haluk et al. (2007) Unconscious, stimulus-dependent priming and conscious, percept-dependent priming with chromatic stimuli. Percept Psychophys 69:550-7
Breitmeyer, Bruno G; Ziegler, Ralph; Hauske, Gert (2007) Central factors contributing to para-contrast modulation of contour and brightness perception. Vis Neurosci 24:191-6
Otto, Thomas U; Ogmen, Haluk; Herzog, Michael H (2006) The flight path of the phoenix--the visible trace of invisible elements in human vision. J Vis 6:1079-86
Breitmeyer, Bruno G; Kafaligonul, Hulusi; Ogmen, Haluk et al. (2006) Meta- and paracontrast reveal differences between contour- and brightness-processing mechanisms. Vision Res 46:2645-58
Ogmen, Haluk; Breitmeyer, Bruno G; Todd, Steven et al. (2006) Target recovery in metacontrast: the effect of contrast. Vision Res 46:4726-34

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