| Locomotion |
1 |
Wilkie, Poulter, & Wann |
Where you look when you learn to steer |
| 2 |
Macuga, Loomis, & Beall |
Two processes in the visual control of steering along a curving path: sensing turns and updating with respect to the path |
| 3 |
Saunders |
A stronger test of the visual heading strategy for guiding locomotion |
| 4 |
Jovancevic, Hayhoe, & Sullivan |
Control of gaze while walking |
| 5 |
Epstein & Higgins |
Moving forward, moving left, and spinning in place: An fMRI study of spatial transformations of the body |
| Attention Mechanisms |
6 |
Muller, Philiastides, & Newsome |
Subthreshold electrical stimulation of monkey superior colliculus (SC) mediates spatial attention |
| 7 |
Clarke & Paradiso |
The complex spatial topography of attentional modulation in macaque V4 |
| 8 |
Ghose & Maunsell |
Flexible center-surround attentional gain fields in V4 neurons |
| 9 |
Chong, Kastner, & Treisman |
Effects of focused and distributed attention on neural competition |
| 10 |
Azoulai, Hubbard, & Ramachandran |
The effect of shape-from-shading on crowding in the periphery |
| 11 |
Dao, Lu, & Dosher |
Orientation bandwidth of selective adaptation |
| Neural Coding |
12 |
Mante & Carandini |
Energy models and the mapping of multiple features in visual cortex |
| 13 |
Saul, Humphrey, & Carras |
Kernel- and model-based predictions of grating responses in monkey and cat visual cortex |
| 14 |
Dumoulin, Dakin, & Hess |
Cortical responses to contours, texture and sparseness: an fMRI investigation. |
| 15 |
Bisley & Goldberg |
Single neuron responses in LIP are similar to the population response. |
| 16 |
Shmuel, Augath, Oeltermann, Pauls, & Logothetis |
Decreases in neuronal activity and negative BOLD response in non-stimulated regions of monkey V1 |
| 17 |
Samonds, Brown, & Bonds |
Relationships between the spatiotemporal structure of spike trains and cortical synchronization |
| Space Perception |
18 |
Girshick, Vishwanath, & Banks |
Pictorial space perception and viewing distance |
| 19 |
Ooi & He |
Quantitative descriptors of the relationships between physical and perceived distances based on the ground surface representation mechanism |
| 20 |
Willemsen, Colton, Creem-Regehr, & Thompson |
Examining Distance Compression in Virtual Environments: Hi-Tech versus No-Tech Displays |
| 21 |
Wu, He, & Ooi |
Stimulus duration and binocular disparity factors in representing the ground surface and localizing object in the intermediate distance range |
| 22 |
Bingham & Mon-Williams |
Visually guided reaching allows both slope and intercept of distance functions to be recalibrated without awareness |
| 23 |
Mapp, Khokhotva, & Ono |
Hitting the target: Relatively easy, yet absolutely impossible? |
| Attention: Selection and Tracking |
24 |
Ruff & Driver |
Attentional preparation for stimulus competition: Psychophysical and fMRI evidence |
| 25 |
Wolfe |
A new, two pathway model describes the role of selective attention in human vision. |
| 26 |
Scholl & Feigenson |
When Out of Sight is Out of Mind: Perceiving Object Persistence Through Occlusion vs. Implosion |
| 27 |
Enns & Oriet |
Perceptual asynchrony: Modularity of consciousness or object updating? |
| 28 |
VanRullen |
Binding "hardwired" vs. "arbitrary" feature conjunctions. |
| 29 |
Alvarez & Cavanagh |
Independent attention resources for the left and right visual hemifields |
| Development: Motion & Form |
30 |
Lewis, Ellemberg, Maurer, Guillemot, & Lepore |
Motion perception in 5-year-olds: Immaturity is related to hypothesized complexity of cortical processing |
| 31 |
Armstrong, Lewis, Ellemberg, Bhagirath, & Maurer |
Comparison of sensitivity to first- and second-order information in infants, children, and adults |
| 32 |
Atkinson, Wattam-Bell, Braddick, Birtles, Barnett, & Cowie |
Form vs motion coherence sensitivity in infants: the dorsal/ventral developmental debate continues |
| 33 |
Wada, Lacroix, von Grünau, Borokhovski, Constantinescu, de Almeida, Gurnsey, & Segalowitz |
Predicting reading performance from motion coherence thresholds in six- and seven-year-old children. |
| 34 |
Lewis, Fine, & Dobkins |
Effects of context on motion processing: the barber pole illusion in infants |
| 35 |
Kovács, Kovács, & Fehér |
Lack of "one-shot" learning in preschool children (eye-movement data) |
| Form and Pattern |
36 |
Rainville & Wilson |
Global form perception in motion-defined radial-frequency contours |
| 37 |
Braddick, Aspell, Atkinson, & Wattam-Bell |
More complex global pattern information shows shorter integration time |
| 38 |
Liu, Lu, & Aguilar |
Perceptual shape regularization |
| 39 |
Landy, Goutcher, Trommershauser, Maloney, & Mamassian |
MEGaVis: Perceptual decisions in the face of explicit costs and benefits |
| 40 |
Purves & Howe |
The statistics of natural scene geometry predict the perception of angles and line orientation |
| 41 |
Andresen & Grill-Spector |
Task dependent modulation of size-sensitivity across human visual cortex |
| Neural Basis of Awareness |
42 |
Tse, Martinez-Conde, Schlegel, & Macknik |
Visibility and visual masking of simple targets is confined to occipital cortex |
| 43 |
Macknik, Martinez-Conde, Schlegel, & Tse |
Dichoptic visual masking reveals localized processing of visibility in human extrastriate cortex |
| 44 |
Whitney, Goltz, & Goodale |
fMRI activity for the unseen: masking in the primary visual cortex |
| 45 |
Haynes, Driver, & Rees |
Human cortical activations related to visual metacontrast masking |
| 46 |
Tong |
Representations of Visual Imagery in Human Primary Visual Cortex |
| 47 |
Wu & Shimojo |
Transcranial magnetic stimulation (TMS) reveals the content of post-perceputal visual processing. |
| Spatial Vision II |
48 |
Frazor & Geisler |
The statistics of local contrast and mean luminance in natural images |
| 49 |
Levi, Klein, & Chen |
What is the signal in noise? |
| 50 |
Taylor, Bennett, & Sekuler |
Noise detection: Optimal summation of orientation information |
| 51 |
Watson & Ahumada |
The Spatial Standard Observer |
| 52 |
MacLeod & Judson |
Does sampling by the cone mosaic limit resolution? |
| 53 |
Sperling & Hsu |
Revisiting the Lincoln Picture Problem |
| Color I - Fundamentals |
54 |
Hong & Shevell |
Chromatic induction from an S-cone background: Evidence for an S-cone specific Center-Surround Receptive Field |
| 55 |
Lindsey & Brown |
Color naming and color consensus: “Blue” is special |
| 56 |
Hardy, Frederick, Kay, & Werner |
Color naming and lens brunescence |
| 57 |
Hillis & Brainard |
Color detection and appearance: A non-linear link |
| 58 |
Werner |
Chromatic adaptation in motion |
| Binocular Rivalry / Bistable Perception |
59 |
Paffen, Tadin, te Pas, van der Smagt, Lappin, & Verstraten |
Center-surround inhibition and facilitation during binocular rivalry |
| 60 |
Watanabe, Paik, & Blake |
Preserved gain control for luminance contrast during binocular rivalry suppression |
| 61 |
Tsuchiya & Koch |
Continuous flash suppression |
| 62 |
Suzuki & Grabowecky |
Long-term speeding of alternations in binocular rivalry: Potential mediation by primary visual cortex. |
| 63 |
Meng & Tong |
Binocular Rivalry and Perceptual Filling-in of Visual Phantoms in Human Visual Cortex |
| Spatial Vision I |
64 |
Puts, Pokorny, & Smith |
Magnocellular and parvocellular mediated Vernier acuity |
| 65 |
Polat & Sagi |
Temporal asymmetry of collinear lateral interactions |
| 66 |
Song & Baker |
A common mechanism underlying neuronal processing of contrast envelopes and illusory contours |
| 67 |
Carrasco, Ling, Gobel, Fuller, & Read |
Attention alters appearance in early vision: Contrast sensitivity, spatial resolution, and color saturation |
| 68 |
Delord, Devinck, & Knoblauch |
Surface and edge in visual detection : Is filling-in necessary? |
| Temporal and Spatial Representation |
69 |
Guttman, Gilroy, & Blake |
When a mixed ensemble sings a common song: Spatial grouping from temporal structure |
| 70 |
Kanai & Verstraten |
Flash-Induced Palinopsia in normal observers: Perceiving the veridical and extrapolated positions simultaneously |
| 71 |
Sundberg, Fallah, & Reynolds |
Neural mechanisms underlying the spatial mislocalization of a flashed element embedded in an apparent motion sequence |
| 72 |
Cantor & Schor |
Does the Temporal Impulse Response Cause the Flash Lag Effect? |
| 73 |
Bridgeman, DiLollo, Enns, & von Muehlenen |
Modeling metacontrast masking with varying target and mask durations |
| 74 |
Ogmen, Breitmeyer, Todd, & Mardon |
Double dissociation in target recovery: Effect of contrast |
| 3D Shape |
75 |
Todd, Thaler, Dijkstra, Koenderink, & Kappers |
The effects of camera and viewing angles on the perception of 3D shape from texture |
| 76 |
Thaler, Dijsktra, & Todd |
On the role of phase information in the perception of 3D shape from texture |
| 77 |
Mamassian & Goutcher |
A Bayesian Model of Structure-from-Motion Perception |
| 78 |
Domini & Caudek |
A new approach to the study of cue-integration |
| 79 |
Khang, Koenderink, & Kappers |
Shape constancy does not hold for images rendered with different types of material surfaces |
| 80 |
Biederman, Kayaert, & Vogels |
Systematic investigation of shape tuning in macaque IT |
| Motion I |
81 |
Martinez-Trujillo, Hopf, Treue, Wildes, Simine, Heinze, & Tsotsos |
A human cortical specialization for the processing of velocity gradients in moving stimuli |
| 82 |
Krekelberg, van Wezel, & Albright |
Speed adaptation in macaque MT |
| 83 |
Thompson & Hammett |
Perceived speed in peripheral vision: it can go up as well as down |
| 84 |
Bhavaraju & Mingolla |
Perception of speed across variations in spatiotemporal frequency |
| 85 |
Backus & Oruc |
Rotating snakes and the failure of motion mechanisms to compensate for early adaptation to luminance |
| 86 |
Campana, Walsh, Casco, & Cowey |
Visual area V5/MT "remembers" what, not where |
| Object Recognition |
87 |
James & Gauthier |
Backward masking reveals greater fMRI activation with primed objects |
| 88 |
Baker, Knouf, Wald, Kwong, Benner, Fischl, & Kanwisher |
Functional selectivity of human extrastriate visual cortex at high resolution |
| 89 |
Kayaert, Op de Beeck, Biederman, & Vogels |
Shape dimension-dependent coding of macaque IT neurons. |
| 90 |
Grill-Spector |
Using multiple functional criteria to define high-level human visual areas in the lateral occipital and temporal lobes. |
| 91 |
Tyler, Likova, & Wade |
Properties of Object Processing in Lateral Occipital Cortex |
| 92 |
Fang & He |
Viewer-Centered Object Representation in Human Visual System Revealed By Viewpoint Aftereffect |
| Object Perception |
93 |
Lazareva, Young, & Wasserman |
Pigeon’s recognition of occluded objects: differential effect of training experience |
| 94 |
Peissig, Kawasaki, & Sheinberg |
Long-term familiarity as measured by visual evoked potentials in the monkey |
| 95 |
Hochstein, Barlasov, Hershler, Nitzan, & Shneor |
Rapid vision is holistic |
| 96 |
Christensen & Todd |
The effects of texture changes on object recognition |
| 97 |
Liu, Jovicich, Baker, Mangini, Wald, & Kanwisher |
A left fusiform region that responds selectively to letter strings |
| 98 |
Hayworth & Biederman |
Parts and relations are analyzable sources of shape variation: Evidence for structural descriptions |
| Eye Movements |
99 |
Johnston & Everling |
Neural activity in monkey prefrontal cortex during delayed-match-to-sample and conditional pro-saccade - anti-saccade tasks |
| 100 |
Ford, Goltz, & Everling |
Anti-saccade performance predicted by event-related fMRI |
| 101 |
Greenlee, Oeyzurt, Vallines, & Rutschmann |
Event-related fMRT during Saccadic Gap- and Overlap-Paradigms: Neural Correlates of Express Saccades |
| 102 |
Hayashi, Andersen, & Shimojo |
Human parietal cortex remaps cue-priming effect across saccades: cortical location and dynamics assessed by transcranial magnetic stimulation. |
| 103 |
Simion & Shimojo |
How Early Does the Brain “Know” What It Likes? Evidence from Pupilometry |
| 104 |
Watanabe, Noritake, Maeda, Tachi, & Nishida |
Space constancy around the time of a saccade for intransient stimuli |
| Motion Integration |
105 |
Norcia, Vildavski, Wade, & Pettet |
Modulation of local motion signals by the global structure of optic flows: evidence for feedback from high-density EEG recordings |
| 106 |
Dakin, Mareschal, & Bex |
Equivalent noise analysis of motion integration |
| 107 |
Tadin, Paffen, Verstraten, Blake, & Lappin |
Perceived 3D surface layout modulates center-surround interactions in motion |
| 108 |
Lappin & Tadin |
Figure-ground segregation by center-surround motion mechanisms |
| 109 |
Benton & Curran |
A speed-tuned effect of coherence on the perceived speed of global motion |
| 110 |
Huk & Shadlen |
Temporal integration of visual motion in macaque parietal cortex |
| Eye Movements and Perception |
111 |
Land |
The coordination of eyes, head and trunk in very large natural gaze saccades |
| 112 |
Connolly, Goodale, Cant, & Munoz |
Preparatory gap and memory-delay fMRI activation in the human frontal eye field is higher for pointing as compared to saccade trials |
| 113 |
Erkelens |
Properties of saccade generation revealed by smooth pursuit |
| 114 |
Braun, Pracejus, & Gegenfurtner |
Smooth pursuit eye movements in response to the motion after effect |
| 115 |
Lipps & Pelz |
Yarbus revisited: task-dependent oculomotor behavior |
| 116 |
Watamaniuk, Velisar, Badler, & Heinen |
Effects of motion adaptation on smooth pursuit performance |
| De Valois Memorial |
117 |
Jacobs |
Asking Monkeys About Color |
| 118 |
Shapley |
Spatial Vision and the Visual Cortex: can we establish a connection? |
| Material Properties |
119 |
Fleming, Adelson, Buelthoff, & Jensen |
Perceiving translucent materials |
| 120 |
Ripamonti, Bloj, Greenwald, & Brainard |
An Equivalent Illumiant Model of How Perceived Lightness Varies with Scene Geometry |
| 121 |
Boyaci & Maloney |
The effect of an illuminant direction cue based on cast shadows on lightness perception in three-dimensional scenes |
| 122 |
Pont, van Doorn, & Koenderink |
Light field matching |
| 123 |
Adelson, Li, & Sharan |
Image statistics for material perception |
| 124 |
Köteles, Vogels, & Orban |
Coding of material properties in macaque inferior-temporal cortex |
| Rapid Scene Perception |
125 |
Sanocki |
The time course with which representations of scene layout become functional |
| 126 |
Maljkovic, Martini, & Farid |
The time-course of categorization of real-life scenes with affective content |
| 127 |
Brockmole & Henderson |
Attentional prioritization of new objects in natural scenes |
| 128 |
Festman & Braun |
Scene comprehension outside the focus of attention. |
| 129 |
Evans & Treisman |
Perception of natural scenes; is it really attention-free? |
| 130 |
Kirchner, Gegenfurtner, Kerzel, & Thorpe |
The role of spatial frequency in ultra-rapid scene categorization |
| Faces I |
131 |
Golarai, Ghahremani, Eberhardt, Grill-Spector, & Gabrieli |
Representation of parts and canonical face configuration in the amygdala, superior temporal sulcus (STS) and the fusiform "face area" (FFA) |
| 132 |
Ng, Ciaramitaro, Fine, & Boynton |
Selective tuning of face perception |
| 133 |
Yovel & Kanwisher |
Face Perception Engages a Domain-Specific System for Processing both Configural and Part-Based Information about Faces |
| 134 |
Schiltz, Caldara, Sorger, Goebel, Mayer, & Rossion |
A critical role of the right fusiform gyrus in individual face discrimination: Evidence from neuroimaging studies of a prosopagnosic patient |
| 135 |
Ganel, Valyear, Goshen-Gottstein, & Goodale |
Greater fMRI activation in the "fusiform face area" for the processing of expression than the processing of identity: Implications for face-recognition models |
| 136 |
Loffler, Wilkinson, Yourganov, & Wilson |
Effect of Facial Geometry on the fMRI signal in the Fusiform Face Area |
| Multisensory Integration |
137 |
Arnold, Johnston, & Nishida |
Timing sight and sound: Determining the temporal tuning of a cross modal interaction. |
| 138 |
Meyer, Roehrbein, Wuerger, & Zetzsche |
The effect of spatial asynchrony on the integration of auditory and visual motion signals |
| 139 |
Buelthoff & Newell |
Distinctive auditory information improves visual face recognition |
| 140 |
Gepshtein, Burge, Banks, & Ernst |
What is an inter-sensory object? Optimal combination of vision and touch depends on their spatial coincidence |
| 141 |
Ciaramitaro, Buracas, & Boynton |
Cross-modal attention effects vary across human visual cortex |
| 142 |
MacNeilage, Berger, Banks, & Buelthoff |
Visual cues are used to interpret gravito-inertial force |
| Visual Control of Hand Movements |
143 |
Greenwald, Knill, & Saunders |
Monocular and binocular cues contribute differently to planning and online control of reaching movements |
| 144 |
Schrater & Flister |
Selecting contact points for reaching |
| 145 |
Trommershauser, Gepshtein, Maloney, Landy, & Banks |
Optimal compensation for changes in effective movement variability in planning movement under risk |
| 146 |
Schlicht, Schrater, & Sloane |
Statistical decision theory for everyday tasks: A natural cost function for human reach and grasp |
| 147 |
Fattori, Breveglieri, Kutz, Marzocchi, & Galletti |
Reach-to-grasp movements modulate neural activity in the dorso-medial visual stream |
| Visual Short-Term Memory |
148 |
Saiki & Miyatsuji |
The role of attention in maintenance of feature binding in visual working memory |
| 149 |
Luck & Zhang |
Fixed resolution, slot-like representations in visual working memory |
| 150 |
Wilken & Ma |
A detection theory account of visual short-term memory for color |
| 151 |
Olson, Jiang, & Sledge |
Increasing the functional capacity of visual short-term memory through attention and long-term memory |
| 152 |
Droll, Hayhoe, Triesch, & Sullivan |
Working memory for object features is influenced by scene context |
| Perception and Action |
153 |
Gorea & Waszak |
Two modus operandi of the motor system in relation to perceptual behavior |
| 154 |
Króliczak, Heard, Goodale, & Gregory |
Target-directed actions resist the hollow-face illusion |
| 155 |
Brouwer, Smeets, & Brenner |
The effect of timing demands varied by shape and speed in hitting moving targets |
| 156 |
Hayhoe, Mennie, Gorgos, Semrau, & Sullivan |
The role of prediction in catching balls. |
| 157 |
McBeath, Sugar, & Wang |
Baseball fielders utilize a rule of constant cotangent change to navigate to catch ground balls |
| Color II - Ramifications |
158 |
Li & Zaidi |
3-D shape from chromatic orientation flows |
| 159 |
Kingdom, Hammamji, & Rangwala |
Cardinal colour contributions to the colour-shading effect |
| 160 |
Gilchrist |
Disentangling object color from illuminant color: The role of gradient correlations |
| 161 |
Balas, Jameson, & Sinha |
The illusion of 'pan-field' color |
| 162 |
Nishida, Watanabe, Tachi, & Kuriki |
Motion-induced colour mixture |
| Search I |
163 |
van den Berg, Beintema, Vlaskamp, Hooge, & van Loon |
Foraging for targets with saccades |
| 164 |
Woodman, Yi, Chun, & Schall |
Masking the mask: Targets are recovered during pattern masking but not object-substitution masking |
| 165 |
Eckstein, Caspi, Beutter, & Pham |
The decoupling of attention and eye movements during multiple fixation search |
| 166 |
Baldassi, Burr, & Megna |
Confidence grows with uncertainty in visual search. |
| 167 |
Verghese & Ma-Wyatt |
Visual search determines whether an object is segmented |
| 168 |
Peterson, Beck, & Vomela |
The guidance of attention by retrospective and prospective memory during visual search. |
| Stereopsis |
169 |
Bredfeldt & Cumming |
Orientation tuning for disparity defined edges in Macaque V2 |
| 170 |
Nienborg, Bridge, Parker, & Cumming |
Temporal resolution for disparity modulation may be limited by the speed of response modulation in V1 |
| 171 |
Rogers & Ambler |
Vertical disparities can recalibrate the vergence system |
| 172 |
Berends, Liu, & Schor |
Adaptation to disparity produced by vertical magnification causes a slant bias at the perceptual level and biased azimuth signals from eye position. |
| 173 |
Banks, Gepshtein, & Rose |
Do we perceive stereoscopic surfaces from patches of constant disparity? |
| 174 |
Sedgwick, Gillam, & Shah |
Stereoscopically perceived depth across surface discontinuities |
| Search II |
175 |
Rosenholtz |
Letter search is influenced by the frequency of occurrence of the letters of the alphabet |
| 176 |
Beck, Peterson, & Vomela |
Where but not what is remembered during visual search |
| 177 |
Hollingworth |
Memory guides search in natural scenes |
| 178 |
Rensink |
The Invariance of Visual Search to Geometric Transformation |
| 179 |
Rauschenberger & Peterson |
When unambiguous stimuli become ambiguous: Spatiotemporal context effects with nominally unambiguous stimuli |
| 180 |
Lleras, Rensink, & Enns |
Rapid Resumption is modulated by high-level strategies. |
| Visual Cortex: Properties and Organization |
181 |
Series, Latham, & Pouget |
Influence of correlated activity on the efficiency of orientation encoding |
| 182 |
Victor, Repucci, & Mechler |
Responses to Hermite function stimuli reveal intrinsically two-dimensional processing in cat V1 |
| 183 |
McAdams & Reid |
The receptive field strength of simple cells can be modulated by attention. |
| 184 |
Freiwald, Tsao, Tootell, & Livingstone |
Complex and dynamic receptive field structure in macaque cortical area V4d |
| 185 |
Krishna, Bisley, & Goldberg |
A rapid, precisely-timed onset response in area LIP of the monkey |
| 186 |
Kamitani & Tong |
Pattern recognition of orientation-selective fMRI signals in the human visual cortex |
| Perceptual Learning & Plasticity |
187 |
Casco, Campana, Grieco, & Fuggetta |
Experience enhances texture saliency by reducing behavioural and cortical responses to irrelevant texture features |
| 188 |
Jiang & Leung |
Implicit learning of ignored visual context |
| 189 |
Fiser, Scholl, & Aslin |
Perception of object trajectories during occlusion constrains statistical learning of visual features |
| 190 |
Ostrovsky, Andalman, & Sinha |
Acquisition of visual function after extended congenital blindness |
| 191 |
Vaina, Soloviev, & Buonanno |
Reorganization of human retinotopic cortical map after an occipital lobe infarct: A longitudinal study |
| Stereo / Depth |
192 |
Buckthought & Stelmach |
Binocular matching of oriented components in stereopsis: Psychophysics and modeling |
| 193 |
Burge, Peterson, & Palmer |
Perceived depth is influenced both by binocular disparity and configural cues. |
| 194 |
Cumming & Read |
The stroboscopic Pulfrich stimulus: A new explanation of an old illusion |
| 195 |
Grove, Brooks, Anderson, & Gillam |
Stereopsis based on transparency: Disparity or a new form of stereopsis? |
| 196 |
Miyawaki |
Signal model of latency delay in visual evoked potential by binocular disparity |
| Perceptual Organization |
197 |
Sugihara, Qiu, & von der Heydt |
Figure-ground organization and attention modulation in neurons of monkey area V2 |
| 198 |
Large, Aldcroft, Kuchinad, & Vilis |
Keeping it together: The maintenance of figure-ground segregation in the lateral occipital sulcus |
| 199 |
Houtkamp & Roelfsema |
Figure-ground and figure-figure segregation in curve tracing |
| 200 |
Palmer & Brooks |
Edge-Texture Grouping: A New Class of Information about Depth and Shape |
| 201 |
Mitroff & Scholl |
Online Grouping and Segmentation Without Awareness: Evidence from Motion-Induced Blindness |
| Amblyopia & Other Visual Disorders |
202 |
Nawrot, Frankl, & Stockert |
Elevated motion parallax thresholds are related to eye movement anomalies in strabismus |
| 203 |
Mendola, Chan, Roy, Conner, Scwartz, Odom, & Kwong |
Loss of visual cortex in children and adults with amblyopia |
| 204 |
Trevethan, Sahraie, & Weiskrantz |
Blindsight superior to 'sighted-sight'? |
| 205 |
Bouvier & Engel |
Patterns of cortical damage in achromatopsia and prosopagnosia |
| 206 |
Betts, Taylor, Bennett, & Sekuler |
Evidence for reduced inhibition in the aging visual system revealed by a motion discrimination task |
| Motion II |
207 |
Cropper |
Colour and Motion: Masking Über Alles |
| 208 |
Chen, Sheliga, FitzGibbon, & Miles |
The short-latency ocular following responses (OFR) elicited by position steps applied to complex grating patterns: evidence for energy-based and feature-based detection of motion. |
| 209 |
Fine, Anderson, Boynton, & Dobkins |
Interactions between contrast, coherence and directional tuning |
| 210 |
Williams, Hubbard, & Ramachandran |
Postdiction in visual motion perception |
| 211 |
Anstis & Macleod |
Fluttering hearts: a new analysis |
| Faces II |
212 |
Cate & Behrmann |
3-D depth influences holistic perception processes in healthy subjects and a prosopagnosic patient |
| 213 |
Giese, Sigala, Wallraven, & Leopold |
Physiologically inspired neural model for the prototype-referenced encoding of faces |
| 214 |
Duchaine, Yovel, Butterworth, & Nakayama |
Elimination of all domain-general hypotheses of prosopagnosia in a single individual: Evidence for an isolated deficit in 2nd order configural face processing |
| 215 |
Fox, McKeeff, & Tong |
A perceptual basis for the lighting of Caravaggio’s faces |
| 216 |
Sinha & Gilad |
Face recognition with ‘Contrast Chimeras’ |
| Biological Motion |
217 |
Westhoff & Troje |
Person identification from biological motion: information content of discrete Fourier components |
| 218 |
Jacobs & Shiffrar |
Walking perception by walking observers |
| 219 |
Loula, Prasad, & Shiffrar |
People watching: visual and motor experience define sensitivity to human movement. |
| 220 |
Morgan & McBeath |
What's the point? Determining the group's center-of-attention |
| 221 |
Casile & Giese |
Possible influences of motor learning on perception of biological motion |
| Adaptation |
222 |
Solomon & Morgan |
The lingering effects of artificial scotomata |
| 223 |
Gur, Kagan, & Snodderly |
Lack of short-term adaptation in V1 cells of the alert monkey |
| 224 |
Brown, Samonds, & Bonds |
Area 18 contributes to contrast adaptation of Area 17 cells in the cat. |
| 225 |
Dhruv, Solomon, & Peirce |
Profound Contrast Adaptation Early in the Visual Pathway |
| 226 |
Kunken, Sun, & Lee |
Modeling macaque ganglion cell response in studies of light adaptation using the Westheimer paradigm |
| Biological motion |
227 |
Troje |
Inverted gravity, not inverted shape impairs biological motion perception |
| 228 |
Johnson |
Interpersonal Meaning in the Body's Motion and Morphology |
| 229 |
Shiffrar, Chouchourelou, & Pinto |
A Social Visual System? |
| 230 |
McAleer, Mazzarino, Volpe, Camurri, Patterson, & Pollick |
Perceiving Animacy and Arousal in Transformed Displays of Human Interaction |
| 231 |
Jordan & Stoner |
Gender-Specific Adaptation of Biological Motion |
| 232 |
Pollick, Paterson, & Mamassian |
Combining faces and movements to recognize affect |
| 233 |
Kitazaki & Inoue |
Perception of human body poses: view dependency and search efficiency |
| 234 |
Hiris, Krebeck, Edmonds, & Stout |
What learning to see the motion of nothing in particular tells us about biological motion perception |
| 235 |
Freire, Maurer, Lewis, & Blake |
Adults are better than 6-year-olds at perceiving biological motion in noise |
| 236 |
Vuong, Hof, Thornton, & Buelthoff |
An advantage for detecting human targets in dynamic versus static composite stimuli |
| 237 |
Jokisch, Daum, & Troje |
Self recognition versus recognition of others by biological motion: Viewpoint-dependent effects |
| 238 |
Hadjigeorgieva, Jang, Park, Jung, Chung, & Pollick |
The influence of temporal offset noise on the perception of possible versus impossible movement |
| 239 |
Grossman, Battelli, & Leone |
TMS over STSp disrupts perception of biological motion |
| Binocular Rivalry / Bistable Perception |
240 |
Kim & Blake |
Color promotes interocular grouping during binocular rivalry |
| 241 |
Beintema, Halfwerk, & van Wezel |
Less rivalry with more biological motion |
| 242 |
Graf |
Binocular surface shape cues influence interocular rivalry |
| 243 |
Sobel, Blake, & Raissian |
Binocular rivalry suppression does impede buildup of the motion aftereffect. |
| 244 |
White |
Binocular rivalry with perceptually ambiguous stimuli yields multistable perceptions |
| 245 |
Makous, Fiser, & Bex |
Contrast averaging in binocular rivalry |
| 246 |
Carmel, Freeman, Lavie, & Rees |
Working memory maintains perceptual biases during binocular rivalry |
| 247 |
Grossmann & Dobbins |
Rotating Kinetic Dot Patterns Stabilize Perceptual Dominance During Binocular Rivalry |
| 248 |
Shinozaki & Takeda |
MEG measurement of higher level visual responses evoked by various types of binocular rivalry stimuli |
| 249 |
Kornmeier & Michael |
Evidence for early visual processing in perceptual disambiguation of ambiguous figures |
| 250 |
Nadasdy & Andersen |
Perceptual decision influences V1 neuronal responses to ambiguous three-dimensional objects |
| 251 |
Saenz & Koch |
Biasing the Percept of Ambiguous Motion Stimuli |
| 252 |
Liu & Gauthier |
Perceptual instability of low contrast letters |
| 253 |
Hal, Tjan, Liu, Lee, & Motamed |
Tracking a stereo-kinetic ellipse |
| 254 |
Hirsch, Egne, Khalil, Lai, & Patel |
Long-range cortical systems and local parietal areas engaged during the multiple percepts of bistable figures suggest a role for "highly influential" neural ensembles in perceptual grouping mechanisms: an fMRI investigation |
| 255 |
Brascamp, van den Berg, & van Ee |
Shared neural circuitry for switching between perceptual states and ocular motor states? |
| Attention, Objects and Context I |
256 |
Morgan, Paul, & Tipper |
Inhibition of return is object-based, not category-based |
| 257 |
Chao & Yeh |
The importance of disengagement in inhibition of return |
| 258 |
Zhou, Chu, Chen, & Li |
Voluntary Modulation of Early and Late Inhibition in Visual Orienting |
| 259 |
DiMase & Chun |
Contextual cueing by real-world scenes |
| 260 |
Junge & Chun |
Implicit Cues Can Guide Attention |
| 261 |
Ambinder & Simons |
Implicit Pattern Detection and Attention Capture |
| 262 |
Leber, Chun, & Widders |
Visual context implicitly guides attentional set |
| 263 |
Dean & Platt |
World-centered spatial representations in posterior cingulate cortex |
| 264 |
Yeh & Lin |
Role of endogenous orienting in object-based and space-based selection |
| 265 |
Lu, Program, & Itti |
Perceptual consequences of feature-based attention |
| 266 |
Xu & Kanwisher |
Attention, feature dimension, and face identity fMRI adaptation in the right fusiform face area |
| 267 |
Seiffert |
Visual attention mediates object control |
| 268 |
Hyun & Luck |
What stage of processing is influenced by four-dot masks? |
| 269 |
Bemis, Franconeri, & Alvarez |
Rapid number estimation: A new paradigm for investigating the rules of objecthood |
| 270 |
Marino & Scholl |
The Role of Closure in Defining the 'Objects' of Object-Based Attention |
| 271 |
Kimchi & Cohen-Savransky |
The effect of perceptual organization on spontaneous allocation of visual attention |
| Visual Cortex, Receptive Fields and Neural Coding |
272 |
Kontsevich & Tyler |
Component analysis of BOLD response |
| 273 |
Zhang, Maruko, Bi, Watanabe, Zheng, Smith, & Chino |
Long-range signal interactions in V2 neurons of macaque monkeys. |
| 274 |
Moore, Alitto, & Usrey |
The influence of stimulus temporal frequency on orientation tuning and direction selectivity in V1 neurons |
| 275 |
Lu, Kraus, & Roe |
Optical imaging of contrast response in functional domains in V1 and V2 of macaque visual cortex |
| 276 |
Graham, Chandler, & Field |
Decorrelation and response equalization with center-surround receptive fields |
| 277 |
Zhan & Baker |
Cortical orientation domains are invariant with carrier type for contrast envelopes |
| 278 |
Ersoy, Kagan, Rucci, & Snodderly |
Modeling the responses of V1 complex cells to natural temporal inputs |
| 279 |
Khaytin, Xu, Collins, Kaskan, Shima, Kaas, & Casagrande |
The Organization of the Middle Temporal Visual Area (MT) in Bush Babies and Owl Monkeys Revealed by Optical Imaging |
| 280 |
Harner & Watanabe |
A self-organizing neural network model of receptive field and map development of motion direction selectivity, orientation, and ocular dominance in V1 and MT |
| 281 |
Yen, Baker, Lachaux, & Gray |
Natural movies evoke precise responses in cat visual cortex that are not predicted from non-uniform Poisson processes |
| 282 |
Zetzsche, Nuding, & Schil |
Measurement of nonlinear 2nd-order kernels with polyspectra |
| 283 |
Field & Wu |
An attempt towards a unified account of non-linearities in visual neurons |
| 284 |
Schneider, Richter, & Kastner |
Retinotopic organization and functional subdivisions of the human lateral geniculate nucleus and superior colliculus |
| Perceptual & Sensorimotor Learning; Adaptation |
285 |
Bruggeman, Rieser, & Pic |
An action system analysis of visuomotor learning |
| 286 |
Ernst & Endress |
The quality of feedback does not affect the rate of visuomotor adaptation |
| 287 |
Pesavento & Schlag |
Perceived sensorimotor simultaneity is learned |
| 288 |
Qi & Backus |
Learning a new cue for motion in depth |
| 289 |
Lu & Liu |
Perceptual learning of speed discrimination enhances motion after effect (MAE) |
| 290 |
Marotta, Keith, & Crawford |
Is reversing prism adaptation global or modular? |
| 291 |
Rajimehr |
Perceptual modulation of orientation-selective adaptation |
| 292 |
Mednick & Boynton |
Perceptual deterioration is specific to background and target orientation. |
| 293 |
Blaser, Domini, & Raymond |
Perceptual learning increases the tilt aftereffect |
| 294 |
Adams, Graf, & Ernst |
Re-learning the light source prior |
| 295 |
Ivanchenko & Jacobs |
Cue-invariant learning for visual slant discrimination |
| 296 |
Doshe & Lu |
Perceptual learning in first- and second-order letter identification |
| 297 |
Liebe, Gold, Busey, & O'Donnell |
Electrophysiological correlates of the effects of perceptual learning on signal and noise in the human visual system |
| 298 |
Song & Jiang |
How configural is implicit learning of repeated visual context? |
| 299 |
Husk, Sekuler, & Bennett |
Specificity of inversion effects in perceptual learning |
| 300 |
Silverman & Welch |
Category learning in the visual processing stream |
| 301 |
Werner, Yamagishi, Seitz, Goda, Sheremata, Kawato, & Watanabe |
Interference in perceptual learning |
| 302 |
Gosselin & Dupuis-Roy |
Isolating the top-down component of perceptual learning |
| 303 |
Hussain, Bennett, & Sekuler |
Specificity of rapid visual learning: Faces versus textures. |
| 304 |
Yu, Kuac, Zhang, Klein, & Levi |
Perceptual learning of contrast discrimination determined by stimulus temporal pattern but not contrast uncertainty |
| 305 |
Garrigan & Kellman |
Is Perceptual Learning Constrained to Operate Through Perceptual (Not Sensory) Representations? |
| 306 |
Petrov, Dosher, & Lu |
Comparable perceptual learning with and without feedback in non-stationary context: Data and model |
| 307 |
Rasche & Wenger |
Changes in decisional criteria and bias during perceptual learning |
| Color |
308 |
Brown & Lindsey |
The color BLUE: The dictionary project |
| 309 |
Griffin |
Optimality of the Basic Colours Categories |
| 310 |
Ferwerda & Chean |
Dalton’s Jungle: a video game for assessing color anomalies in children’s vision |
| 311 |
Smith & Taboada |
A white-LED based dual-channel Maxwellian view stimulator for vision research |
| 312 |
Furuta, Kuriki, & Nakadomari |
Categorical color perception with color aphasia |
| 313 |
Krauskopf |
Measurement of the relative sensitivity of the L and M cones |
| 314 |
Lee, Pizlo, & Allebach |
Characterization of red-green and yellow-blue opponent channels |
| 315 |
Eskew, Wang, & Richters |
A five-mechanism model of hue sensations |
| 316 |
Khan & Pattanaik |
Modelling blue shift in moonlit scenes using rod cone interaction |
| 317 |
Neriani & Nagy |
Combining information in different color mechanisms: use of cardinal color mechanisms vs. higher-order color mechanisms |
| 318 |
Liu, Brewer, & Wandell |
Variations in temporal and chromatic responses across human visual cortex |
| 319 |
Robson, Holder, Moreland, & Kulikowski |
Chromatic VEP specification of macular pigmentation: comparison with minimum motion and minimum flicker profiles. |
| 320 |
Kuriki |
Chromatic contrast sensitivity during slow temporal modulation in surrounding area |
| 321 |
Reeves, Amano, & Foster |
Gaps in color constancy |
| 322 |
Doerschner, Boyaci, & Maloney |
Estimating the glossiness transfer function induced by changing illumination and testing its transitivity |
| 323 |
Zemach & Teller |
Infants' spontaneous hue preferences are not due solely to variations in perceived saturation |
| 324 |
Goolsby, Grabowecky, & Suzuki |
Task demands modulate the global-form contingency of the Color Suppression Effect |
| 325 |
Xian & Shevell |
Color Appearance Influenced by Local Induction and by Perceptual Grouping |
| 326 |
Yamauchi & Uchikawa |
Depth information affects the judgment of the surface-color mode appearance |
| 327 |
Uchikawa, Yokoi, & Yamauchi |
Ca |
