Guy A Orban researcher ORCID ID = 0000-0002-8179-9584
Orban, Guy A., 1945-....
Orban, Guy A.
VIAF ID: 269128465 (Personal)
Permalink: http://viaf.org/viaf/269128465
Preferred Forms
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100 0 _ ‡a Guy A Orban ‡c researcher ORCID ID = 0000-0002-8179-9584
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100 1 _ ‡a Orban, Guy A.
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100 1 _ ‡a Orban, Guy A. ‡d 1945-
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100 1 _ ‡a Orban, Guy A. ‡d 1945-
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100 1 0 ‡a Orban, Guy A., ‡d 1945-
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100 1 _ ‡a Orban, Guy A., ‡d 1945-....
4xx's: Alternate Name Forms (7)
5xx's: Related Names (2)
Works
Title | Sources |
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Artificial and biological vision systems, c1992: |
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Cognitive neuroscience |
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The neural substrate of orientation working memory. |
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The neuronal machinery involved in successive orientation discrimination. |
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Neuronal operations in the visual cortex |
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A New Cat Fos Antibody to Localize the Immediate Early Gene c-fos in Mammalian Visual Cortex after Sensory Stimulation |
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Not all observed actions are perceived equally |
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Observing Others Speak or Sing Activates Spt and Neighboring Parietal Cortex |
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Occlusion cues contribute to orientation judgments of occlusion-defined contours |
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The organization of orientation selectivity throughout macaque visual cortex |
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The organization of the posterior parietal cortex devoted to upper limb actions: An fMRI study |
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Orientation discrimination of objects and gratings compared: an fMRI study. |
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The overlap of the EBA and the MT/V5 cluster. |
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Parietal representation of symbolic and nonsymbolic magnitude. |
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Perception of Three-Dimensional Shape From Specular Highlights, Deformations of Shading, and Other Types of Visual Information |
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Positron-emission tomography imaging of long-term shape recognition challenges. |
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Practising orientation identification improves orientation coding in V1 neurons. |
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Preferences for horizontal or vertical orientation in cat visual cortical neurones [proceedings] |
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Proceedings: Simple cells in area 18 of the cat? |
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Processing of abstract ordinal knowledge in the horizontal segment of the intraparietal sulcus. |
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Processing of kinetically defined boundaries in the cortical motion area MT of the macaque monkey |
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Processing of targets in smooth or apparent motion along the vertical in the human brain: an fMRI study. |
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The processing of three-dimensional shape from disparity in the human brain. |
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Processing of vocalizations in humans and monkeys: a comparative fMRI study. |
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Properties of striate hypercomplex cells in the cat |
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The quantitative nature of a visual task differentiates between ventral and dorsal stream. |
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Receptive field types of area 18 neurones in the cat |
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Regional brain activity during shape recognition impaired by a scopolamine challenge to encoding. |
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Regions in the human brain activated by simultaneous orientation discrimination: a study with positron emission tomography. |
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The representation of tool use in humans and monkeys: common and uniquely human features |
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Response latencies of visual cells in macaque areas V1, V2 and V5 |
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The response variability of striate cortical neurons in the behaving monkey |
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Responses of macaque inferior temporal neurons to overlapping shapes. |
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Responses of monkey infero-temporal units in an orientation discrimination task. |
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Responses of visual cortical neurons to curved stimuli and chevrons |
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Retinotopic coding of extraretinal pursuit signals in early visual cortex. |
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The retinotopic organization of primate dorsal V4 and surrounding areas: A functional magnetic resonance imaging study in awake monkeys. |
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The retinotopic organization of the human middle temporal area MT/V5 and its cortical neighbors. |
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The Role of Lateral Occipitotemporal Junction and Area MT/V5 in the Visual Analysis of Upper-Limb Postures |
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The role of putative human anterior intraparietal sulcus area in observed manipulative action discrimination |
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Scopolamine-induced impairment of delayed recognition of abstract visual shapes. |
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Search for color 'center(s)' in macaque visual cortex |
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Searching for a salient target involves frontal regions. |
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Seeing biological actions in 3D: An fMRI study |
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Selectivity for 3D Shape That Reveals Distinct Areas Within Macaque Inferior Temporal Cortex |
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Selectivity of cat area 18 neurons for direction and speed in depth. |
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Selectivity of neuronal adaptation does not match response selectivity: a single-cell study of the FMRI adaptation paradigm. |
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The Selectivity of Neurons in the Macaque Fundus of the Superior Temporal Area for Three-Dimensional Structure from Motion |
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Shape Selectivity for Camouflage-Breaking Dynamic Stimuli in Dorsal V4 Neurons |
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Similarities and differences in motion processing between the human and macaque brain: evidence from fMRI. |
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Simulated self-motion in a visual gravity field: sensitivity to vertical and horizontal heading in the human brain. |
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Size and shape of receptive fields in the medial superior temporal area (MST) of the macaque. |
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The Speed Tuning of Medial Superior Temporal (Mst) Cell Responses to Optic-Flow Components |
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Spike Recognition and On-Line Classification by Unsupervised Learning System |
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[Stability of spatial perception depending on ocular saccades] |
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Stable readout of observed actions from format-dependent activity of monkey's anterior intraparietal neurons |
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Stereopsis activates V3A and caudal intraparietal areas in macaques and humans. |
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Stimul : a flexible computer system for stimulus control, data acquisition and on/off line analysis of single unit recordings [proceedings] |
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The suppressive influence of moving textured backgrounds on responses of cat striate neurons to moving bars |
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Task dependency of visual processing in the human visual system. |
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Texture segregation in the cat: a parametric study |
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The transition in the ventral stream from feature to real-world entity representations |
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Unit responses to moving stimuli in area 18 of the cat |
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Using functional magnetic resonance imaging to assess adaptation and size invariance of shape processing by humans and monkeys. |
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Velocity discrimination in the cat. |
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Velocity sensitivity mechanisms in cat visual cortex. |
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Velocity sensitivity of areas 17 and 18 of the cat |
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vision, mission du cerveau les trois révolutions des neurosciences [leçon inaugurale prononcée le jeudi 22 mars 2007] |
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Visual activation in prefrontal cortex is stronger in monkeys than in humans. |
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[Visual and acoustic convergence in the neurons of the anterior tubercle of the corpora quadrigemina in cats] |
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Visual cortical mechanisms of movement perception |
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Visual evoked potentials elicited by a moving unidimensional noise pattern |
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Visual motion processing investigated using contrast agent-enhanced fMRI in awake behaving monkeys. |
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What is the Speed of Transparent and Kinetic-Boundary Displays? |
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Which animal model for understanding human navigation in a three-dimensional world? |
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