Your search keyword '"Vladimir Y. Vildavski"' showing total 24 results

1. Distinct neural sources underlying visual word form processing as revealed by steady state visual evoked potentials (SSVEP)

Author

Fang Wang, Blair Kaneshiro, C. Benjamin Strauber, Lindsey Hasak, Quynh Trang H. Nguyen, Alexandra Yakovleva, Vladimir Y. Vildavski, Anthony M. Norcia, and Bruce D. McCandliss

Subjects

Medicine, Science

Abstract

Abstract EEG has been central to investigations of the time course of various neural functions underpinning visual word recognition. Recently the steady-state visual evoked potential (SSVEP) paradigm has been increasingly adopted for word recognition studies due to its high signal-to-noise ratio. Such studies, however, have been typically framed around a single source in the left ventral occipitotemporal cortex (vOT). Here, we combine SSVEP recorded from 16 adult native English speakers with a data-driven spatial filtering approach—Reliable Components Analysis (RCA)—to elucidate distinct functional sources with overlapping yet separable time courses and topographies that emerge when contrasting words with pseudofont visual controls. The first component topography was maximal over left vOT regions with a shorter latency (approximately 180 ms). A second component was maximal over more dorsal parietal regions with a longer latency (approximately 260 ms). Both components consistently emerged across a range of parameter manipulations including changes in the spatial overlap between successive stimuli, and changes in both base and deviation frequency. We then contrasted word-in-nonword and word-in-pseudoword to test the hierarchical processing mechanisms underlying visual word recognition. Results suggest that these hierarchical contrasts fail to evoke a unitary component that might be reasonably associated with lexical access.

Published

2021

2. Fine Structure of Posterior Alpha Rhythm in Human EEG: Frequency Components, Their Cortical Sources, and Temporal Behavior

Author

Elham Barzegaran, Vladimir Y. Vildavski, and Maria G. Knyazeva

Subjects

Medicine, Science

Abstract

Abstract Heterogeneity of the posterior alpha rhythm (AR) is a widely assumed but rarely tested phenomenon. We decomposed the posterior AR in the cortical source space with a 3-way PARAFAC technique, taking into account the spatial, frequency, and temporal aspects of mid-density EEG. We found a multicomponent AR structure in 90% of a group of 29 healthy adults. The typical resting-state structure consisted of a high-frequency occipito-parietal component of the AR (ARC1) and a low-frequency occipito-temporal component (ARC2), characterized by individual dynamics in time. In a few cases, we found a 3-component structure, with two ARC1s and one ARC2. The AR structures were stable in their frequency and spatial features over weeks to months, thus representing individual EEG alpha phenotypes. Cortical topography, individual stability, and similarity to the primate AR organization link ARC1 to the dorsal visual stream and ARC2 to the ventral one. Understanding how many and what kind of posterior AR components contribute to the EEG is essential for clinical neuroscience as an objective basis for AR segmentation and for interpreting AR dynamics under various conditions, both normal and pathological, which can selectively affect individual components.

Published

2017

3. Distinct neural sources underlying visual word form processing as revealed by steady state visual evoked potentials (SSVEP)

Author

Anthony M. Norcia, C. Benjamin Strauber, Quynh Nguyen, Vladimir Y. Vildavski, Blair Kaneshiro, Alexandra Yakovleva, Bruce D. McCandliss, Lindsey Hasak, and Fang Wang

Subjects

Adult, Male, Steady state (electronics), Adolescent, Computer science, Speech recognition, Science, Visual evoked potentials, Electroencephalography, Article, medicine, Humans, Psychology, Visual Word, Evoked potential, Latency (engineering), Form processing, Multidisciplinary, medicine.diagnostic_test, Middle Aged, Temporal Lobe, Reading, Word recognition, Visual Perception, Evoked Potentials, Visual, Medicine, Female, Neuroscience

Abstract

EEG has been central to investigations of the time course of various neural functions underpinning visual word recognition. Recently the steady-state visual evoked potential (SSVEP) paradigm has been increasingly adopted for word recognition studies due to its high signal-to-noise ratio. Such studies, however, have been typically framed around a single source in the left ventral occipitotemporal cortex (vOT). Here, we combine SSVEP recorded from 16 adult native English speakers with a data-driven spatial filtering approach—Reliable Components Analysis (RCA)—to elucidate distinct functional sources with overlapping yet separable time courses and topographies that emerge when contrasting words with pseudofont visual controls. The first component topography was maximal over left vOT regions with a shorter latency (approximately 180 ms). A second component was maximal over more dorsal parietal regions with a longer latency (approximately 260 ms). Both components consistently emerged across a range of parameter manipulations including changes in the spatial overlap between successive stimuli, and changes in both base and deviation frequency. We then contrasted word-in-nonword and word-in-pseudoword to test the hierarchical processing mechanisms underlying visual word recognition. Results suggest that these hierarchical contrasts fail to evoke a unitary component that might be reasonably associated with lexical access.

Published

2021

4. Neural Sources Underlying Visual Word Form Processing as Revealed by Steady State Visual Evoked Potentials (SSVEP)

Author

L. Hasak, Anthony M. Norcia, Vladimir Y. Vildavski, Forea Wang, Bruce D. McCandliss, Blair Kaneshiro, Alexandra Yakovleva, C. B. Strauber, and Q. T. H. Nguyen

Subjects

Form processing, Steady state (electronics), medicine.diagnostic_test, Computer science, Speech recognition, Word recognition, medicine, Visual evoked potentials, Visual Word, Latency (engineering), Electroencephalography, Evoked potential

Abstract

EEG has been central to investigations of the time course of various neural functions underpinning visual word recognition. Recently the steady-state visual evoked potential (SSVEP) paradigm has been increasingly adopted for word recognition studies due to its high signal-to-noise ratio. Such studies, however, have been typically framed around a single source in the left ventral occipitotemporal cortex (vOT). Here, we combine SSVEP recorded from 16 adult native English speakers with a data-driven spatial filtering approach - Reliable Components Analysis (RCA) - to elucidate distinct functional sources with overlapping yet separable time courses and topographies that emerge when contrasting words with pseudofont visual controls. The first component topography was maximal over left vOT regions with an shorter latency (approximately 180 msec). A second component was maximal over more dorsal parietal regions with a longer latency (approximately 260 msec). Both components consistently emerged across a range of parameter manipulations including changes in the spatial overlap between successive stimuli, and changes in both base and deviation frequency. We then contrasted word-in-nonword and word-in-pseudoword to test the hierarchical processing mechanisms underlying visual word recognition. Results suggest that these hierarchical contrasts fail to evoke a unitary component that might be reasonably associated with lexical access.

Published

2021

5. PseudoSloan: A perimetric-complexity and area-controlled font for vision and reading research

Author

Joss Parsey, Luca Lo Verde, Vladimir Y. Vildavski, Gail Blumberg, and Anthony M. Norcia

Subjects

business.industry, Computer science, media_common.quotation_subject, Visual Acuity, computer.software_genre, Sensory Systems, Ophthalmology, Pattern Recognition, Visual, Reading, Reading (process), Font, Humans, Visual Field Tests, Artificial intelligence, business, computer, Vision, Ocular, Natural language processing, media_common

Abstract

Artificial orthographies have long been used in studies of verbal learning and reading. These orthographies, also known as pseudo or false fonts, are designed to match the letters of an existing alphabet on a range of visual features, isolating effects of orthography from those owing to lexical processing. In a parallel line of research, there has been much interest in the design of optotypes for measuring visual acuity that have good properties in terms of character complexity and graceful degradation under blur. Here we merge these two traditions by designing a fully scalable pseudofont, "PseudoSloan," that is based on the design rubric of the widely used Sloan optotypes. The font includes 26 Latin letters as well as two sets of letter-like symbols matching the Latin alphabet on a letter-by-letter basis. Quantitative matching of the pairs of Sloan and PseudoSloan glyphs is done on the basis of ink area and perimetric complexity. We provide the installable PseudoSloan font in TrueType and OpenType formats, plus a large number of PseudoSloan glyphs in .svg format that vary over wide ranges in their perimetric complexity and ink area (https://osf.io/qhj2b/).

Published

2021

6. Fine Structure of Posterior Alpha Rhythm in Human EEG: Frequency Components, Their Cortical Sources, and Temporal Behavior

Author

Maria G. Knyazeva, Vladimir Y. Vildavski, and Elham Barzegaran

Subjects

Dorsum, Multidisciplinary, medicine.diagnostic_test, business.industry, Science, 05 social sciences, Structure (category theory), Biology, Electroencephalography, Article, 050105 experimental psychology, 03 medical and health sciences, 0302 clinical medicine, Alpha rhythm, medicine, Medicine, 0501 psychology and cognitive sciences, Segmentation, Artificial intelligence, business, Neuroscience, 030217 neurology & neurosurgery, Eeg alpha

Abstract

Heterogeneity of the posterior alpha rhythm (AR) is a widely assumed but rarely tested phenomenon. We decomposed the posterior AR in the cortical source space with a 3-way PARAFAC technique, taking into account the spatial, frequency, and temporal aspects of mid-density EEG. We found a multicomponent AR structure in 90% of a group of 29 healthy adults. The typical resting-state structure consisted of a high-frequency occipito-parietal component of the AR (ARC1) and a low-frequency occipito-temporal component (ARC2), characterized by individual dynamics in time. In a few cases, we found a 3-component structure, with two ARC1s and one ARC2. The AR structures were stable in their frequency and spatial features over weeks to months, thus representing individual EEG alpha phenotypes. Cortical topography, individual stability, and similarity to the primate AR organization link ARC1 to the dorsal visual stream and ARC2 to the ventral one. Understanding how many and what kind of posterior AR components contribute to the EEG is essential for clinical neuroscience as an objective basis for AR segmentation and for interpreting AR dynamics under various conditions, both normal and pathological, which can selectively affect individual components.

Published

2017

7. Frequency but not phase specific modulation of binocular rivalry with transcranial alternating current stimulation

Author

Riesen G, Anthony M. Norcia, Delgado J, and Vladimir Y. Vildavski

Subjects

Physics, Binocular rivalry, medicine.medical_specialty, Visual perception, genetic structures, 05 social sciences, Stimulation, Audiology, Stimulus (physiology), 050105 experimental psychology, eye diseases, 03 medical and health sciences, Left eye, 0302 clinical medicine, medicine, 0501 psychology and cognitive sciences, sense organs, 030217 neurology & neurosurgery, Transcranial alternating current stimulation

Abstract

Recent transcranial alternating current stimulation (tACS) literature suggests that tACS effects can in principle be both frequency and phase specific. In a series of three experiments using 69 participants used binocular rivalry percepts as a read-out for the effects of phase-synchronized tACS stimulation. To test for phase specificity, with frequency the same in each eye, we visually stimulated each eye with 3Hz, with stimuli in each eye presented in temporal in antiphase. The frequency-specific paradigm visually stimulated the right eye with 3Hz, and the left eye with 5Hz. Each experiment was accompanied by 3Hz tACS, whose phase with respect to the visual stimulus was varied by 0°, 90°, 180°, or 270° in relation to the right eye’s stimulus. A baseline no-tACS block preceded the stimulation blocks and two more followed, immediately and ten minutes after. Individual blocks lasted 4 minutes. Additionally, a no-tACS control experiment identical to the 3 Hz anti-phase visual stimuli setup was conducted, keeping all parameters the same but eliminating tACS. During stimulation, the 3 Hz anti-phase visual stimuli setup slowed the rate of rivalry in both eyes. Conversely, the 3Hz-right, 5Hz-left setup slowed the right (targeted) eye significantly while leaving the left (unstimulated) eye unchanged. In both experiments, durations returned to baseline after 10 minutes. Our results are consistent with the frequency-specific model of tACS, and with the Leveltian hypothesis that stimulation weakens the stimulated eye, as the right eye got weaker when it was directly targeted, and both eyes got weaker when targeted in antiphase. tACS does not appear to preferentially modulating percept durations in one phase more than in another.

Published

2019

8. Aging of human alpha rhythm

Author

Vladimir Y. Vildavski, Elham Barzegaran, Jean-François Démonet, and Maria G. Knyazeva

Subjects

0301 basic medicine, Adult, Male, Aging, 03 medical and health sciences, Young Adult, 0302 clinical medicine, Alpha rhythm, Source localization, Aging brain, Humans, Aged, Aged, 80 and over, Resting state fMRI, Chemistry, General Neuroscience, Brain, Signal Processing, Computer-Assisted, Middle Aged, Alpha Rhythm, 030104 developmental biology, Data Interpretation, Statistical, Female, Neurology (clinical), Geriatrics and Gerontology, Neuroscience, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Alpha rhythm (AR) changes are the most pronounced electroencephalogram phenomenon in the aging brain. We analyzed them based on the inherent AR structure obtained by parallel factor analysis decomposition in the cortical source space. AR showed a stable multicomponent structure in 78% of sixty 20- to 81-year-old healthy adults. Typically, it consists of 2 components. The distribution of the higher frequency occipito-parietal component widens with age, with its maximum moving from BA18/19 to BA37. The low-frequency component originating from the occipito-temporal regions in young adults also moves anteriorly with age, while maintaining its maximum within BA37. Both components slow down by 1 Hz over the adult lifespan. The multicomponent AR is more common in younger subjects, whereas a single-component AR in older subjects. This uneven occurrence as well as the increasing spatial and frequency overlaps between components suggest transformation of the multicomponent AR into the single-component AR with age. A detailed knowledge of AR component structure would be useful to monitor age-related neurodegenerative processes in humans.

Published

2017

9. Cue-Invariant Networks for Figure and Background Processing in Human Visual Cortex

Author

Mark W. Pettet, Alex R. Wade, Lawrence G. Appelbaum, Anthony M. Norcia, and Vladimir Y. Vildavski

Subjects

Adult, media_common.quotation_subject, Electroencephalography, Brain mapping, Article, Contrast Sensitivity, Orientation, Perception, Image Processing, Computer-Assisted, medicine, Humans, Attention, Invariant (mathematics), Size Perception, Visual Cortex, media_common, Brain Mapping, medicine.diagnostic_test, business.industry, Spectrum Analysis, General Neuroscience, Pattern recognition, Figure–ground, Magnetic Resonance Imaging, Oxygen, Visual cortex, medicine.anatomical_structure, Pattern Recognition, Visual, Space Perception, Multivariate Analysis, Artificial intelligence, Cues, Visual Fields, business, Psychology, Functional magnetic resonance imaging, Neuroscience, Photic Stimulation

Abstract

Lateral occipital cortical areas are involved in the perception of objects, but it is not clear how these areas interact with first tier visual areas. Using synthetic images portraying a simple texture-defined figure and an electrophysiological paradigm that allows us to monitor cortical responses to figure and background regions separately, we found distinct neuronal networks responsible for the processing of each region. The figure region of our displays was tagged with one temporal frequency (3.0 Hz) and the background region with another (3.6 Hz). Spectral analysis was used to separate the responses to the two regions during their simultaneous presentation. Distributed source reconstructions were made by using the minimum norm method, and cortical current density was measured in a set of visual areas defined on retinotopic and functional criteria with the use of functional magnetic resonance imaging. The results of the main experiments, combined with a set of control experiments, indicate that the figure region, but not the background, was routed preferentially to lateral cortex. A separate network extending from first tier through more dorsal areas responded preferentially to the background region. The figure-related responses were mostly invariant with respect to the texture types used to define the figure, did not depend on its spatial location or size, and mostly were unaffected by attentional instructions. Because of the emergent nature of a segmented figure in our displays, feedback from higher cortical areas is a likely candidate for the selection mechanism by which the figure region is routed to lateral occipital cortex.

Published

2006

10. Assessment of OLED displays for vision research

Author

Vladimir Y. Vildavski, Joyce E. Farrell, Haomiao Jiang, Emily A. Cooper, and Anthony M. Norcia

Subjects

Visual perception, Biomedical Research, Computer science, media_common.quotation_subject, Luminance, Medical and Health Sciences, spectrum, CRTS, Computer-Assisted, Spatio-Temporal Analysis, Methods, OLED, Contrast (vision), Humans, Computer vision, Organic Chemicals, Set (psychology), Eye Disease and Disorders of Vision, Lighting, media_common, spatio-temporal precision, display characterization, Pixel, business.industry, stimulus presentation, Psychology and Cognitive Sciences, Tin Compounds, Signal Processing, Computer-Assisted, Experimental Psychology, Sensory Systems, Ophthalmology, Gamma correction, Computer Terminals, Signal Processing, Data Display, Artificial intelligence, business

Abstract

Vision researchers rely on visual display technology for the presentation of stimuli to human and nonhuman observers. Verifying that the desired and displayed visual patterns match along dimensions such as luminance, spectrum, and spatial and temporal frequency is an essential part of developing controlled experiments. With cathode-ray tubes (CRTs) becoming virtually unavailable on the commercial market, it is useful to determine the characteristics of newly available displays based on organic light emitting diode (OLED) panels to determine how well they may serve to produce visual stimuli. This report describes a series of measurements summarizing the properties of images displayed on two commercially available OLED displays: the Sony Trimaster EL BVM-F250 and PVM-2541. The results show that the OLED displays have large contrast ratios, wide color gamuts, and precise, well-behaved temporal responses. Correct adjustment of the settings on both models produced luminance nonlinearities that were well predicted by a power function ("gamma correction"). Both displays have adjustable pixel independence and can be set to have little to no spatial pixel interactions. OLED displays appear to be a suitable, or even preferable, option for many vision research applications.

Published

2013

11. Connecting the dots: how local structure affects global integration in infants

Author

Vladimir Y. Vildavski, Chuan Hou, Melanie Palomares, Anthony M. Norcia, and Mark W. Pettet

Subjects

Adult, Global integration, Time Factors, Cognitive Neuroscience, media_common.quotation_subject, Luminance, Article, Discrimination, Psychological, Contrast (vision), Humans, Sensitivity (control systems), Visibility, media_common, Communication, Orientation (computer vision), business.industry, Infant, Pattern recognition, Pattern Recognition, Visual, Space Perception, Line (geometry), Evoked Potentials, Visual, Artificial intelligence, Psychology, business, Photic Stimulation, Interpolation

Abstract

Glass patterns are moirés created from a sparse random-dot field paired with its spatially shifted copy. Because discrimination of these patterns is not based on local features, they have been used extensively to study global integration processes. Here, we investigated whether 4- to 5.5-month-old infants are sensitive to the global structure of Glass patterns by measuring visual-evoked potentials. Although we found strong responses to the appearance of the constituent dots, we found sensitivity to the global structure of the Glass patterns in the infants only over a very limited range of spatial separation. In contrast, we observed robust responses in the infants when we connected the dot pairs of the Glass pattern with lines. Moreover, both infants and adults showed differential responses to exchanges between line patterns portraying different global structures. A control study varying luminance contrast in adults suggests that infant sensitivity to global structure is not primarily limited by reduced element visibility. Together our results suggest that the insensitivity to structure in conventional Glass patterns is due to inefficiencies in extracting the local orientation cues generated by the dot pairs. Once the local orientations are made unambiguous or when the interpolation span is small, infants can integrate these signals over the image.

Published

2009

12. Event-related potentials show configural specificity of global form processing

Author

Vladimir Y. Vildavski, Anthony M. Norcia, Francesca Pei, and Mark W. Pettet

Subjects

Form processing, business.industry, General Neuroscience, Pattern recognition, Moiré pattern, Concentric, medicine.anatomical_structure, Visual cortex, Pattern Recognition, Visual, Extrastriate cortex, Event-related potential, medicine, Dilation (morphology), Evoked Potentials, Visual, Humans, Linear complex structure, Artificial intelligence, Psychology, business, Neuroscience, Photic Stimulation, Visual Cortex

Abstract

Glass patterns are a type of moire created when a random-dot field is overlaid with a rotated, translated or dilated copy. The overall form of the moire cannot be detected using local processing mechanisms, and because of this, Glass patterns are useful probes of global form processing. Here, we use event-related potentials to show that certain global organizations (concentric structure created by rotation and radial structure produced by dilation) produce much larger brain responses than others (linear structure created by translation). The results are consistent with the existence of specialized form processing mechanisms in the extrastriate cortex.

Published

2005

13. Temporal dynamics of the human response to symmetry

Author

Christopher W. Tyler, T. Rowan Candy, Anthony M. Norcia, Vladimir Y. Vildavski, and Mark W. Pettet

Subjects

Adult, Male, Property (programming), Phase (waves), Measure (mathematics), Image (mathematics), Extrastriate cortex, medicine, Humans, Visual Pathways, Statistical physics, Visual Cortex, Physics, Communication, Quantitative Biology::Neurons and Cognition, business.industry, Middle Aged, Sensory Systems, Form Perception, Ophthalmology, medicine.anatomical_structure, Pattern Recognition, Visual, Feature (computer vision), Evoked Potentials, Visual, Female, Symmetry (geometry), business, Phenomenology (particle physics)

Abstract

Symmetry is a highly salient feature of animals, plants, and the constructed environment. Although the perceptual phenomenology of symmetry processing is well understood, little is known about the underlying neural mechanisms. Here we use visual evoked potentials to measure the time course of neural events associated with the extraction of symmetry in random dot fields. We presented sparse random dot patterns that were symmetric about both the vertical and horizontal axes. Symmetric patterns were alternated with random patterns of the same density every 500 msec, using new exemplars of symmetric and random patterns on each image update. Random/random exchanges were used as a control. The response to updates of random patterns was multiphasic, consisting of P65, N90, P110, N140 and P220 peaks. The response to symmetric/random sequences was indistinguishable from that for random/random sequences up to about 220 msec, after which the response to symmetric patterns became relatively more negative. Symmetry in random dot patterns thus appears to be extracted after an initial response phase that is indifferent to configuration. These results are consistent with the hypothesis (Lee, Mumford, Romero, & Lamme, 1998; Tyler & Baseler, 1998) that the symmetry property is extracted by processing in extrastriate cortex. Keywords: evoked potentials, shape, form

Published

2001

14. Visual evoked potentials for dynamic Glass pattern perception in 4- month old infants

Author

Mark W. Pettet, Anthony M. Norcia, Vladimir Y. Vildavski, Chuan Hou, and Melanie Palomares

Subjects

Ophthalmology, medicine.medical_specialty, medicine, Pattern perception, Visual evoked potentials, Audiology, Psychology, Sensory Systems

Published

2010

15. Disparity processing in the human brain imaged with high density EEG

Author

Suzanne P. McKee, Greg Appelbaum, Alex R. Wade, Vladimir Y. Vildavski, Mark W. Pettet, and Tony Norcia

Subjects

Physics, Ophthalmology, medicine.anatomical_structure, medicine, Human brain, High density eeg, Neuroscience, Sensory Systems

Published

2010

16. fMRI of Glass patterns

Author

Anthony M. Norcia, Vladimir Y. Vildavski, Mark W. Pettet, and Alex R. Wade

Subjects

Ophthalmology, Computer science, Sensory Systems

Published

2010

17. Regions of human visual cortex sensitive to small vernier offsets as determined by EEG source-imaging

Author

Alex R. Wade, Anthony M. Norcia, Mark W. Pettet, L. Greg Appelbaum, and Vladimir Y. Vildavski

Subjects

Physics, medicine.diagnostic_test, business.industry, Vernier scale, Electroencephalography, P200, Sensory Systems, law.invention, Ophthalmology, Visual cortex, medicine.anatomical_structure, law, medicine, Computer vision, Artificial intelligence, Source imaging, business

Published

2010

18. On the differences and similarities between real and implied motion: a high-density EEG study

Author

Mark W. Pettet, Vladimir Y. Vildavski, Greg Appelbaum, Melanie Palomares, Alex R. Wade, and Anthony M. Norcia

Subjects

Ophthalmology, Communication, medicine.diagnostic_test, business.industry, Computer science, medicine, Pattern recognition, Artificial intelligence, Electroencephalography, business, Sensory Systems, Motion (physics)

Published

2010

19. Cortical networks underlying scene segmentation

Author

Alex R. Wade, Mark W. Pettet, Vladimir Y. Vildavski, Anthony M. Norcia, and Greg Appelbaum

Subjects

Ophthalmology, Scene segmentation, business.industry, Computer science, Computer vision, Artificial intelligence, business, Sensory Systems

Published

2010

20. Modulation of local and global motion responses by sustained visual attention

Author

Anthony M. Norcia, L. Gregory Appelbaum, Ying Han, Alex R. Wade, Mark W. Pettet, and Vladimir Y. Vildavski

Subjects

Ophthalmology, Modulation, Computer science, business.industry, Visual attention, Computer vision, Artificial intelligence, business, Sensory Systems, Motion (physics)

Published

2010

21. Neural dynamics of visual scene segmentation

Author

Anthony M. Norcia, Vladimir Y. Vildavski, Mark W. Pettet, Lawrence G. Appelbaum, and Alex R. Wade

Subjects

Ophthalmology, Scene segmentation, Computer science, business.industry, Dynamics (music), Segmentation-based object categorization, Scale-space segmentation, Computer vision, Artificial intelligence, business, Sensory Systems

Published

2010

22. Figure-ground interaction in the human visual cortex

Author

Mark W. Pettet, Lawrence G. Appelbaum, Vladimir Y. Vildavski, Anthony M. Norcia, and Alex R. Wade

Subjects

Adult, Models, Neurological, Classification of discontinuities, Texture (music), Retina, Article, Form perception, medicine, Humans, Visual Cortex, Brain Mapping, Communication, Orientation (computer vision), business.industry, Electroencephalography, Figure–ground, Magnetic Resonance Imaging, Sensory Systems, Form Perception, Ophthalmology, Visual cortex, medicine.anatomical_structure, Nonlinear Dynamics, Feature (computer vision), Space Perception, Retinotopy, Multivariate Analysis, business, Cartography, Photic Stimulation, Geology

Abstract

Discontinuities in feature maps serve as important cues for the location of object boundaries. Here we used multi-input nonlinear analysis methods and EEG source imaging to assess the role of several different boundary cues in visual scene segmentation. Synthetic figure/ground displays portraying a circular figure region were defined solely by differences in the temporal frequency of the figure and background regions in the limiting case and by the addition of orientation or relative alignment cues in other cases. The use of distinct temporal frequencies made it possible to separately record responses arising from each region and to characterize the nature of nonlinear interactions between the two regions as measured in a set of retinotopically and functionally defined cortical areas. Figure/background interactions were prominent in retinotopic areas, and in an extra-striate region lying dorsal and anterior to area MT+. Figure/background interaction was greatly diminished by the elimination of orientation cues, the introduction of small gaps between the two regions, or by the presence of a constant second-order border between regions. Nonlinear figure/background interactions therefore carry spatially precise, time-locked information about the continuity/discontinuity of oriented texture fields. This information is widely distributed throughout occipital areas, including areas that do not display strong retinotopy.

Published

2008

23. Dynamics of texture segmentation

Author

Alex R. Wade, Mark W. Pettet, Vladimir Y. Vildavski, Anthony M. Norcia, and Greg Appelbaum

Subjects

business.industry, Segmentation-based object categorization, Computer science, Scale-space segmentation, Pattern recognition, Image segmentation, Texture (geology), Sensory Systems, Ophthalmology, Image texture, Region growing, Segmentation, Artificial intelligence, business

Published

2005

24. Modulation of local motion signals by the global structure of optic flows: evidence for feedback from high-density EEG recordings

Author

Mark W. Pettet, Vladimir Y. Vildavski, Alex R. Wade, and Anthony M. Norcia

Subjects

Physics, Ophthalmology, Optics, Modulation, business.industry, High density eeg, Global structure, business, Optic Flows, Sensory Systems, Motion (physics)

Published

2004