| Q47283619 | 2015 Charles F. Prentice Medal Award Lecture: Neural Organization of Binocular Vision |
| Q48906239 | 3D shape perception from combined depth cues in human visual cortex |
| Q45911173 | 50 Years of Stereoblindness: Reconciliation of a Continuum of Disparity Detectors With Blindness for Disparity in Near or Far Depth. |
| Q35092679 | 7 tesla FMRI reveals systematic functional organization for binocular disparity in dorsal visual cortex |
| Q35679827 | A Neural Model of Distance-Dependent Percept of Object Size Constancy |
| Q48371364 | A model for neural representation of binocular disparity in striate cortex: distributed representation and veto mechanism |
| Q36568176 | A proto-object based saliency model in three-dimensional space |
| Q34055492 | A reaction-diffusion model to capture disparity selectivity in primary visual cortex |
| Q41087050 | Abnormal motion processing and binocularity: infantile esotropia as a model system for effects of early interruptions of binocularity |
| Q48701145 | Activation in visual cortex correlates with the awareness of stereoscopic depth. |
| Q64092960 | Adaptation reveals multi-stage coding of visual duration |
| Q36591900 | Adaptation to natural binocular disparities in primate V1 explained by a generalized energy model |
| Q48382675 | At least at the level of inferior temporal cortex, the stereo correspondence problem is solved |
| Q30447572 | Audio-visual perception of 3D cinematography: an fMRI study using condition-based and computation-based analyses |
| Q72024632 | Behavioral studies of local stereopsis and disparity vergence in monkeys |
| Q79291797 | Binocular Deficits Associated With Early Alternating Monocular Defocus. II. Neurophysiological Observations |
| Q42027636 | Binocular eye movement control and motion perception: what is being tracked? |
| Q39089537 | Binocular function during unequal monocular input |
| Q48372688 | Binocular interaction and disparity coding in area 19 of visual cortex in normal and split-chiasm cats |
| Q49080410 | Binocular interactions and disparity coding in area 21a of cat extrastriate visual cortex |
| Q72630239 | Binocular interactions and steady-state VEPs. A study in normal and defective binocular vision (Part II) |
| Q67841274 | Binocular phase specificity of striate cortical neurones |
| Q27303109 | Binocular stereoscopy in visual areas V-2, V-3, and V-3A of the macaque monkey |
| Q33567126 | Binocular visual surface perception |
| Q39117607 | Bringing the real world into the fMRI scanner: repetition effects for pictures versus real objects |
| Q28277335 | Causing and curing infantile esotropia in primates: the role of decorrelated binocular input (an American Ophthalmological Society thesis) |
| Q37217921 | Chapter 21 Visual agnosia. |
| Q35126779 | Coding of stereoscopic depth information in visual areas V3 and V3A. |
| Q48560354 | Common neural processing regions for dynamic and static stereopsis in human parieto-occipital cortices |
| Q79947507 | Contribution of area MT to stereoscopic depth perception: choice-related response modulations reflect task strategy |
| Q48324412 | Contribution of middle temporal area to coarse depth discrimination: comparison of neuronal and psychophysical sensitivity. |
| Q28280566 | Cortical area MT and the perception of stereoscopic depth |
| Q30665397 | Cortical mechanisms of binocular stereoscopic vision. |
| Q52994329 | Depth aftereffects mediated by vertical disparities: evidence for vertical disparity driven calibration of extraretinal signals during stereopsis. |
| Q46208384 | Depth is encoded in the visual cortex by a specialized receptive field structure |
| Q72989047 | Depth selectivity of vertical fusional mechanisms |
| Q48101963 | Depth-related visually evoked potentials by dynamic random-dot stereograms in humans: negative correlation between the peaks elicited by convergent and divergent disparities |
| Q48376553 | Differential patterns of 2D location versus depth decoding along the visual hierarchy |
| Q48351242 | Disparity coding in the cat: a comparison between areas 17-18 and area 19. |
| Q52394356 | Disparity-tuned channels of the human visual system. |
| Q34159826 | Disparity-tuned population responses from human visual cortex |
| Q48089670 | Dissociation between vergence and binocular disparity cues in the control of prehension |
| Q41190350 | Dynamic stabilization of receptive fields of cortical neurons (VI) during fixation of gaze in the macaque |
| Q35911887 | Early computational processing in binocular vision and depth perception. |
| Q48844051 | Evidence of Stereoscopic Surface Disambiguation in the Responses of V1 Neurons. |
| Q37503943 | Fast and Forceful: Modulation of Response Activation Induced by Shifts of Perceived Depth in Virtual 3D Space |
| Q30485980 | Fine discrimination training alters the causal contribution of macaque area MT to depth perception |
| Q50305570 | Generation of dynamic random-element stereograms in real time with a system based on a personal computer |
| Q48824982 | Global speed averaging is tuned for binocular disparity. |
| Q34317662 | Head-direction cells in the rat posterior cortex. II. Contributions of visual and ideothetic information to the directional firing |
| Q35959296 | Ideal Binocular Disparity Detectors Learned Using Independent Subspace Analysis on Binocular Natural Image Pairs |
| Q33815930 | Improved discrimination of visual stimuli following repetitive transcranial magnetic stimulation |
| Q27302975 | Insect stereopsis demonstrated using a 3D insect cinema. |
| Q36671384 | Intrinsic signal optical imaging evidence for dorsal V3 in the prosimian galago (Otolemur garnettii). |
| Q36841255 | Intrinsic-signal optical imaging reveals cryptic ocular dominance columns in primary visual cortex of New World owl monkeys |
| Q30480120 | Linking neural representation to function in stereoscopic depth perception: roles of the middle temporal area in coarse versus fine disparity discrimination |
| Q27305307 | Local Integration Accounts for Weak Selectivity of Mouse Neocortical Parvalbumin Interneurons. |
| Q48707761 | Macaque inferior temporal neurons are selective for three-dimensional boundaries and surfaces. |
| Q46466693 | Mechanisms of stereoscopic vision: the disparity energy model. |
| Q37012603 | Mechanisms underlying the transformation of disparity signals from V1 to V2 in the macaque |
| Q92964545 | Mice Discriminate Stereoscopic Surfaces Without Fixating in Depth |
| Q42962183 | Modeling the shape hierarchy for visually guided grasping |
| Q98282896 | Modelling binocular disparity processing from statistics in natural scenes |
| Q48459804 | Modulation of cell responses to horizontal disparities by ocular vergence in the visual cortex of the awake Macaca mulatta monkey. |
| Q35697051 | Monocular preferences in binocular viewing |
| Q91721114 | Multivariate Analysis of BOLD Activation Patterns Recovers Graded Depth Representations in Human Visual and Parietal Cortex |
| Q34708085 | Natural-scene statistics predict how the figure-ground cue of convexity affects human depth perception |
| Q40851021 | Neural coding of 3D features of objects for hand action in the parietal cortex of the monkey |
| Q48693272 | Neural correlates of fine depth discrimination in monkey inferior temporal cortex. |
| Q74715200 | Neural mechanisms underlying stereoscopic vision |
| Q33995404 | Neural modulation by binocular disparity greatest in human dorsal visual stream |
| Q21558384 | Neuroimaging of amblyopia and binocular vision: a review |
| Q52192144 | Neuronal responses to edges defined by luminance vs. temporal texture in macaque area V1. |
| Q43161647 | Object speed derived from the integration of motion in the image plane and motion-in-depth signaled by stereomotion and looming |
| Q34471143 | Ocular Dominance Predicts Neither Strength Nor Class of Disparity Selectivity With Random-Dot Stimuli in Primate V1 |
| Q41911183 | Optimal disparity estimation in natural stereo images |
| Q34491778 | Organization of disparity-selective neurons in macaque area MT. |
| Q70668276 | Oscillatory binocular system and temporal segmentation of stereoscopic depth surfaces |
| Q81446026 | Pictorial cues constrain depth in da Vinci stereopsis |
| Q83227746 | Population rate-coding predicts correctly that human sound localization depends on sound intensity |
| Q48823494 | Postnatal development of binocular disparity sensitivity in neurons of the primate visual cortex. |
| Q48127044 | Receptive fields of disparity-selective neurons in macaque striate cortex |
| Q48337898 | Receptive fields of disparity-tuned simple cells in macaque V1. |
| Q37014199 | Recurrent connectivity can account for the dynamics of disparity processing in V1. |
| Q51614821 | Rejection of false matches for binocular correspondence in macaque visual cortical area V4. |
| Q38848928 | Relating functional connectivity in V1 neural circuits and 3D natural scenes using Boltzmann machines. |
| Q35924843 | Relative luminance and binocular disparity preferences are correlated in macaque primary visual cortex, matching natural scene statistics |
| Q56067833 | Representation of stereoscopic edges in monkey visual cortex |
| Q49046174 | Response latencies to visual stimulation and disparity sensitivity in single cells of the awake Macaca mulatta visual cortex. |
| Q48625020 | Responses of primary visual cortical neurons to binocular disparity without depth perception |
| Q34692819 | Responses to interocular disparity correlation in the human cerebral cortex. |
| Q58695758 | Revisiting the functional significance of binocular cues for perceiving motion-in-depth |
| Q33846506 | Seeing in three dimensions: the neurophysiology of stereopsis. |
| Q30504432 | Sensitivity of human visual cortical area V6 to stereoscopic depth gradients associated with self-motion |
| Q46412017 | Sensitivity to relative disparity in early visual cortex of pigmented and albino ferrets |
| Q33940231 | Separating fusion from rivalry |
| Q24642394 | Similarities in normal and binocularly rivalrous viewing |
| Q48289676 | Simultaneous mapping of binocular and monocular receptive fields in awake monkeys for calibrating eye alignment in a dichoptical setup |
| Q40408364 | Solving da Vinci stereopsis with depth-edge-selective V2 cells |
| Q73399984 | Spatio-temporal dynamics of depth propagation on uniform region |
| Q79447373 | Stereo channels with different temporal frequency tunings |
| Q48236922 | Stereopsis activates V3A and caudal intraparietal areas in macaques and humans |
| Q47138389 | Stereoscopic processing of crossed and uncrossed disparities in the human visual cortex |
| Q74595271 | Stereoscopic segregation of transparent surfaces and the effect of motion contrast |
| Q48362010 | Stereoscopic transparency: a test for binocular vision's disambiguating power |
| Q41688047 | Stereoscopic vision: Which parts of the brain are involved? |
| Q63484978 | Structural and Functional Changes across the Visual Cortex of a Patient with Visual Form Agnosia |
| Q35086255 | Suppressive mechanisms in monkey V1 help to solve the stereo correspondence problem. |
| Q73022575 | Temporal integration for stereoscopic vision |
| Q41553663 | The TINS Lecture. The parietal association cortex in depth perception and visual control of hand action. |
| Q24676981 | The cortical column: a structure without a function |
| Q48592599 | The development of stereoacuity in infant rhesus monkeys |
| Q77350823 | The effects of contrast on perceived depth and depth discrimination |
| Q37180890 | The organization of orientation-selective, luminance-change and binocular- preference domains in the second (V2) and third (V3) visual areas of New World owl monkeys as revealed by intrinsic signal optical imaging |
| Q73704499 | The precision of single neuron responses in cortical area V1 during stereoscopic depth judgments |
| Q48800370 | The processing of three-dimensional shape from disparity in the human brain. |
| Q37442815 | The representation of object distance: evidence from neuroimaging and neuropsychology |
| Q41683724 | The subregion correspondence model of binocular simple cells |
| Q60042468 | Three-Dimensional Shape Coding in Inferior Temporal Cortex |
| Q34069022 | Transfer of perceptual learning of depth discrimination between local and global stereograms |
| Q46086976 | Unconscious adaptation: a new illusion of depth induced by stimulus features without depth |
| Q73119755 | Visual responses in monkey areas V1 and V2 to three-dimensional surface configurations |