| 1 |
Woller, Barnes, Payne, & Lomber |
Reversal of visual hemineglect: Differential influences of deactivating either contralateral posterior parietal cortex or the superior colliculus |
| 2 |
Raymond, Tavasolli, & Fenske |
Selective visual attention to novel stimuli determines emotional responses |
| 3 |
Payne, Lomber, Schmidt, & Galuske |
Feedback Circuits: Link to ability to redirect attention |
| 4 |
Maciokas, Svec, & Crognale |
Attentional changes with age: Evidence from attentional blink deficits |
| 5 |
Loula & Carrasco |
Information accrual for unattended shapes in negative priming |
| 6 |
Hubbard, Krishnan, & Ramachandran |
Reduced crowding with illusory contours supports an attentional locus for crowding |
| 7 |
Hamker & VanRullen |
The time course of attentional selection among competing locations |
| 8 |
Giersch |
Interactions between spatial attention and the processing of discontinuities |
| 9 |
Humphreys, Jung-Stallmann, & Olivers |
An analysis of the time course of visual marking |
| 10 |
Fine & Reeves |
Processing benefits from diffuse attention when the stimuli are harder to discriminate |
| 11 |
Festa-Martino, Gindes, & Heindel |
Driving and covert orienting: Differential effects of dual-task conditions on selective attention and arousal |
| 12 |
Fernandez-Duque & Black |
Object localization without object recognition in the split brain: A possible role for spatial attention |
| 13 |
Brown, Breitmeyer, Hand, & Browning |
Sex differences in shifting attention within and between objects |
| 14 |
Breitmeryer, Brown, Leighty, & Williamson |
Configuration and distance interact to determine object- or space-based attetnional deployment |
| 15 |
Awh, Matsukura, & Serences |
Top-down modulation of biased competition during covert spatial orienting |
| 16 |
Cavanaugh & Wurtz |
Change blindness for motion in macaque monkey |
| 17 |
Ua Cruadhlaoich & Roe |
Quantitative comparison of ocular dominance column width in optical images |
| 18 |
Orbach, Henderson, & Baker |
Signal detection theory and implicit representation |
| 19 |
Ogmen & Breitmeyer |
Dissociation between visual awareness and sensori-motor performance fails in paracontrast but not metacontrast |
| 20 |
Kouhsari, Rajimehr, Afraz, & Esteky |
Visual illusion without awareness |
| 21 |
May, Tsiappoutas, & Flanagan |
Peripheral disappearance elicited by abrupt contrast decrements |
| 22 |
Haase & Fisk |
Signal Detection Theory as a modeling tool for resolving controversies surrounding unconscious perception |
| 23 |
Dodds, Machado, Rafal, & Ro |
A temporal /nasal asymmetry for blindsight: Evidence for extrageniculate mediation. |
| 24 |
Scavetta, Jones, Mitchell, & Murphy |
NMDA-dependent recovery of visual acuity following monocular deprivation |
| 25 |
Lewis, Ellemberg, Maurer, Lee, Brent, & Levin |
The effects of early pattern deprivation on the development of the ability to detect local motion and to discriminate its velocity |
| 26 |
Wu & Shimojo |
TMS reveals the correct location of flashes in motion-mislocalization illusions |
| 27 |
Shioiri, Yamamoto, & Yaguchi |
Effect of attention on flash lagging |
| 28 |
Hubbard & Motes |
Memory for initial position: A Fröhlich Effect or an Onset Repulsion Effect? |
| 29 |
Cantor & Schor |
Flash lag in the frequency domain |
| 30 |
Cai & Cavanagh |
Motion interpolation of a unique feature into stimulus gaps and blind spots |
| 31 |
Tjan, Chung, & Legge |
O letter channels, where art thou? |
| 32 |
Lawton |
Figure/Ground and left-right movement discrimination developing when child is learning to read |
| 33 |
Florer & Preston |
Optimal letterspacing for reading can be learned |
| 34 |
Crewther, Kiely, Laycock, & Crewther |
The role of transients in object recognition for good and poor readers |
| 35 |
Chung |
Learning to identify unfamiliar letters in central and peripheral vision |
| 36 |
Strasberger |
Invariance of the psychometric function's slope across the visual field, for contrast-dependent character recognition |
| 37 |
Uka & DeAngelis |
MT neurons do not signal relative disparity |
| 38 |
Perrone & Krauzlis |
Simulating the time course of MT neuron responses with a model based on V1 neuron properties |
| 39 |
Perge, Borghuis, Duijnhouwer, Lankheet, & van Wezel |
Direction tuning of macaque MT neurons: a reverse correlation study |
| 40 |
Zosh, Vuong, & Tarr |
Lights, camera, action! An interaction between illumination and viewpoint change in object recognition |
| 41 |
Vuong & Tarr |
Not all views are created equal: Object identity momentum via dynamic displays |
| 42 |
Thoma & Davidoff |
Priming for depth-rotated objects depends on attention |
| 43 |
Pani, Chariker, & Dawson |
Learning new structural descriptions in the understanding of elementary motions |
| 44 |
Kimura, Miura, & Shinohara |
Interaction of viewer centered representation and object centered representation of three dimensional space |
| 45 |
James, Humphrey, Gati, Menon, & Goodale |
Differing viewpoint effects in the ventral and dorsal visual streams revealed using fMRI |
| 46 |
James, Humphrey, & Goodale |
Viewpoint preferences during the exploration of novel 3D objects |
| 47 |
Herbert, Nodsle, & Williford |
Detecting depth rotated bilateral symmetry |
| 48 |
Cate & Behrmann |
Image complexity determines degree of viewpoint dependence |
| 49 |
Boutet, Reeve, & Chaudhuri |
The influence of attention on the recognition of depth-rotated objects and faces |
| 50 |
Bennett |
Evidence for a pre-match 'mental translation' on a form-matching task |
| 51 |
Yonas, Bruggeman, & Konczak |
The role of binocular information in the control of perception and action |
| 52 |
Westwood & Goodale |
Grasping remembered objects: Pinpointing the transition between on-line and off-line visuomotor control modes |
| 53 |
Philbeck |
More errors in an action-based response: blindfolded walking and the horizontal-vertical illusion |
| 54 |
Kwok & Braddick |
The effect of the Titchener circles illusion on grasping and manual estimation of two and three dimensional targets |
| 55 |
Dunn & Thompson |
Different illusory effects of the Judd illusion for perception and action after a temporal delay |
| 56 |
Dassonville & Bala |
Roelofs' illusion provides evidence against a perception/action dissociation |
| 57 |
Creem-Regehr, Gooch, & Thompson |
Perceiving virtual geographical slant: action influences perception |
| 58 |
Chubb, Wright, Anderson, & Kim |
Psychophysical dissociation of "how" and "what" tasks in normal participants |
| 59 |
Ashida |
'Representational momentum' in reaching action |
| 60 |
Andre & Rogers |
Perceivers walk the walk but talk short: Evidence for two visual pathways in distance perception |
| 61 |
Vishton & Coulston |
Abrupt stimulus motion eliminates task-specific immunity to pictorial illusions |
| 62 |
Zwick, Stuck, Brown, Ruiz, & Lund |
Neural plasticity and accidental human laser macular injury |
| 63 |
Yi & Chun |
Shape-specific perceptual learning in a figure-ground segregation task |
| 64 |
Poggel, Müller-Oehring, Kasten, Bunzenthal, & Sabel |
Topographical patterns of visual field recovery: Changes of objective and subjective visual field size in brain-lesioned patients |
| 65 |
Notman & Sowden |
Does categorical perception result from perceptual learning? |
| 66 |
Mednick, Pathak, Nakayama, & Stickgold |
Perceptual deterioration predicts performance today |
| 67 |
Lu & Dosher |
Using external noise methods to isolate mechanisms of attention/perceptual learning |
| 68 |
Lu, Lu, & Dosher |
Perceptual learning in peripheral vision with attention reflects (mostly) template retuning |
| 69 |
Lomber |
Learning to see the trees before the forest: Reversible deactivation of the superior colliculus during learning of local and global visual features |
| 70 |
Kung, Rossion, Vuong, & Tarr |
How does object processing change with perceptual expertise? |
| 71 |
Kozma, Kovács, & Fehér |
Learning only after sleep in a contour integration task |
| 72 |
Koyama, Harner, & Watanabe |
Task-dependency of tuning characteristics change in the course of perceptual learning |
| 73 |
Kao, Beardsley, & Vaina |
Perceptual learning of motion-pattern discrimination: Psychophysics and computational modeling |
| 74 |
Hiles, Intrator, & Edelman |
Unsupervised learning of visual structure |
| 75 |
Furmanski & Engel |
Perceptual learning in human primary visual cortex |
| 76 |
Cousineau |
Learning categorization mapping with a race model |
| 77 |
Chu, Lu, & Dosher |
Perceptual learning of motion direction discrimination in fovea reflects mixed but separable mechanisms of stimulus enhancement and template retuning |
| 78 |
Zavagno |
Anomalous contours prevent brightness spreading in phantom illumination displays |
| 79 |
Swaminathan & Grossberg |
Laminar cortical mechanisms for the perception of slanted and curved 3-D surfaces and their 2-D pictorical projections |
| 80 |
Sohn, Blaser, Vidnyánszky, & Papathomas |
Surface based mechanisms of attentional facilitation and inhibition in motion perception |
| 81 |
Singh |
The role of convexity and part structure in modal and amodal completion |
| 82 |
Scheessele & Pizlo |
A computational model of the perception of partially occluded figures |
| 83 |
Oruc, Maloney, & Landy |
Testing optimal Gaussian cue combination models with possibly correlated depth cues |
| 84 |
Norman, Norman, Lee, Stockton, & Lappin |
The visual perception of length along intrinsically curved surfaces |
| 85 |
MacKenzie, Wilcox, & Abramovitz |
Surface interpolation and illusory boundary formation in stereoscopic images: the role of local element properties |
| 86 |
Liu & Todd |
The perception of convex and concave surfaces under natural lighting conditions |
| 87 |
Koenderink, van Doorn, Kappers, te Pas, & Pont |
Perceiving illumination direction in 3D texture |
| 88 |
Kandil & Fahle |
The notion of 'purely time-based figure-ground segregation' is still justified |
| 89 |
Holcombe |
A dynamic but motionless cue for occlusion- and its consequences |
| 90 |
Fleming, Williams, & Anderson |
Resolving figure-ground ambiguity |
| 91 |
Börjesson & Poom |
Visual slant-contrast across space and attributes |
| 92 |
Blaser, Vidnyanszky, & Papathomas |
Relative motion, not polarity, breaks 'surface tension' |
| 93 |
Berzhanskaya, Swaminathan, Beck, & Mingolla |
Highlights and surface gloss perception |
| 94 |
Bertone & Faubert |
The interactive effects of symmetry and binocular disparity on visual surface representation |
| 95 |
Bertenthal |
Visual occlusion and infants' predictive tracking |
| 96 |
Berends, Zhang, Tanaka, & Schor |
Eye movements facilitate simultaneous and sequential slant discrimination |
| 97 |
Amati & Elder |
Slant capture in the perception of multiple textured transparent surfaces |
| 98 |
Adams & Mamassian |
Incomplete transfer between tilt and slant after-effects |
| 99 |
Xu, Bosking, Sáry, Jones, Royal, Stefansic, Shima, Fitzpatrick, & Casagrande |
The functional organization of orientation maps in owl monkey V1 and V2 revealed by optical imaging of intrinsic signals |
| 100 |
Seitz & Grossberg |
How do laminar circuits coordinate their development in the visual cortex? The role of the cortical subplate. |
| 101 |
Schultz, del Prete, & Panzeri |
Signalling properties of bursts and spikes in model thalamic relay cells |
| 102 |
Owaki & Takeda |
The first whole-head recordings of multifocal visually evoked magnetic field (VEF) |
| 103 |
Laverghetta & Shimizu |
Parallel processing in the visual system of zebra finches |
| 104 |
Zhu, Lin, & Kasamatsu |
Asymmetrical response modulation between cell pair in cat striate cortex |
| 105 |
Kagan, Gur, & Snodderly |
Analysis of responses to drifting and stationary gratings in V1 of alert monkey |
| 106 |
Hansen & Neumann |
A computational model of recurrent, colinear long-range interaction in V1 for contour enhancement and junction detection |
| 107 |
Gockeln, Riegert, Tutschke, & Winter |
Multifocal topographical evoked potential mapping |
| 108 |
Dorn & Ringach |
Long-range interactions in macaque primary visual cortex |
| 109 |
Conner, Sharma, & Mendola |
Retinotopic mapping in children with normal vision |
| 110 |
Chelvanayagam, Hu, & Vidyasagar |
Neural spike irregularity in adjacent cells of the same visual cortical column are unrelated despite other shared properties |
| 111 |
Kingdom & Kasrai |
Colour contrast can facilitate perceived 3D shape-from-shading |
| 112 |
Li & Zaidi |
Isotropic textures convey distance not 3-D shape |
| 113 |
Todd, Oomes, Koenderink, & Kappers |
The perception of 3D shape from anisotropic texture patterns |
| 114 |
Madison & Kersten |
Perceiving depth from reflection |
| 115 |
Fahle, Morgan, Diehl, & Spang |
An fMRI correlate of perceived 3-dimensional structure from purely temporal information |
| 116 |
Vanduffel, Fize, Peuskens, Denys, Sunaert, Todd, & Orban |
Processing 3-dimensional structure from motion in humans and macaques |
| 117 |
Lages, Mamassian, & Graf |
Spatial and temporal tuning of motion-in-depth perception |
| 118 |
Suzuki |
Selective attention linearly weights inputs prior to population coding of shape |
| 119 |
Merigan |
Shape selectivity of V4 neurons for stimuli whose discrimination depends on V4 |
| 120 |
Pasupathy & Connor |
Population coding of complex shapes in macaque area V4 |
| 121 |
Hess & Ledgeway |
Direction- and speed-defined spatial contours; one mechansim or two? |
| 122 |
Kourtzi, Bülthoff, Erb, & Grodd |
Shape processing in the human motion area MT/MST |
| 123 |
Adams & Horton |
Shadows from retinal blood vessels cause local amblyopia by deprivation of photoreceptors |
| 124 |
Mechler & Ringach |
Re-evaluating the dichotomy between simple and complex cells in primary visual cortex (V1) |
| 125 |
Snodderly, Kagan, & Gur |
Receptive fields and quasi-linear response modulation in V1 of alert macaques |
| 126 |
Dragoi, Sharma, Miller, & Sur |
Dynamics of neuronal sensitivity in primate V1 underlying local feature discrimination |
| 127 |
Livingstone & Conway |
Responses of V1 neurons to reverse phi stimuli |
| 128 |
Zenger-Landolt & Heeger |
Surround suppression in human V1 explains psychophysical lateral masking |
| 129 |
Duncan & Boynton |
Cortical magnification factor in human primary visual cortex correlates with Vernier acuity thresholds |
| 130 |
Olshausen |
Sparse coding of time-varying natural images |
| 131 |
McDermott |
Psychophysics with junctions in real images |
| 132 |
Geisler & Diehl |
Natural scene statistics and Bayesian natural selection |
| 133 |
Victor, Hardy, & Conte |
Visual processing of image statistics: Qualitative differences between local and global statistics; quantitative differences between low- and high-order statistics |
| 134 |
Olman, Schrater, & Kersten |
BOLD fMRI response to natural images |
| 135 |
Wong, Levi, Barrett, & Pacey |
Non-linear transformation of sinusoidal gratings in amblyopia |
| 136 |
Simmers & Bex |
What is the nature of the spatial deficit in amblyopia? |
| 137 |
Wolf & Hurlbert |
Influences of chromatic texture on contrast induction |
| 138 |
Van Arsdel & Loop |
Color thresholds in normal dichromats |
| 139 |
Uchida & Uchikawa |
Influence of higher order chromatic mechanisms on inhomogeneous chromatic discrimination |
| 140 |
Svec, Reiner, & Webster |
Chromatic contrast and neural adjustments to blur |
| 141 |
Smithson & Zaidi |
Partitions of object colour space under illuminant and background changes |
| 142 |
Shapiro, Baldwin, & Zaidi |
Time course of L-M system adaptation to simple and complex fields |
| 143 |
Patel, Chung, Bedell, & Ogmen |
Color and motion: which is the tortoise and which is the hare? |
| 144 |
Malkoc, Webster, & Kay |
Individual differences in color categories |
| 145 |
Logvinenko & Hutchinson |
Which colours do not invoke the high-spatial-frequency tritanopia effect? |
| 146 |
Kuriki |
Chromatic signal-to-noise ratio affects chromatic gamut effect |
| 147 |
Khang & Zaidi |
Illuminant color perception of spectrally filtered spotlights |
| 148 |
Hutchinson & Logvinenko |
An effect of sinusoidal temporal modulation on high-spatial-frequency tritanopia |
| 149 |
Edwards & Hogben |
Colour effects on metacontrast masking and reading |
| 150 |
Dillenburger & Wehrhahn |
Vastly differing variances in the ratio of red and green cones between female and male human observers |
| 151 |
Delahunt & Brainard |
Comparison of color constancy with respect to illumination changes induced by distinct physical processes |
| 152 |
Crognale, Gerth, & Werner |
Multifocal chromatic pattern-onset VEPs |
| 153 |
Buckelmuller, Cardinal, & KiperInst |
The categorization of colors measured with the Stroop effect |
| 154 |
Bloj, Wolfe, & Hurlbert |
The perception of colour gradients |
| 155 |
Billock & Tsou |
Hue, saturation and brightness: fundamental properties of color vision derived from dynamic interactions between cortical cell populations |
| 156 |
Welchman & Harris |
Studying eye movements produced whilst making visual decisions |
| 157 |
Wada & von Grünau |
The role of eye movements and induced motion on the strength of a trajectory illusion |
| 158 |
Tehovnik, Slocum, & Schiller |
Electrical properties of elements mediating saccadic eye movements within macaque V1: excitability differences between layers |
| 159 |
Silva, Bradshaw, & Groeger |
The role of action-relevance in the perception and representation of natural scenes |
| 160 |
Shorter-Jacobi, Murthy, Thompson, & Schall |
Neural correlates of divided orienting in frontal eye field in a search-step task |
| 161 |
Sharma, Dragoi, MIller, & Sur |
Modulation of responses in mokey V1 by an eye position task |
| 162 |
Rizzo, Moon, Wilkinson, Bateman, Jermeland, & Schnell |
Ocular search of simulated roadway displays in drivers with constricted visual fields |
| 163 |
Peterson & Kramer |
Covert shifts of attention precede involuntary eye movements |
| 164 |
Park, Schlag-Rey, & Schlag |
Localization precedes attention-induced acceleration of visual processing |
| 165 |
Noritake & Yagi |
Is the phantom array an evidence for Discrete-EPI model? |
| 166 |
Nieman, Hayashi, Andersen, & Shimojo |
Gaze modulation of visual aftereffects in color and depth |
| 167 |
Naji & Freeman |
Pursuit eye-movements disambiguate depth order in an ambiguous motion display |
| 168 |
Mizushina & Uchikawa |
Peripheral, not fovea, vision detects displacement of a background across saccade |
| 169 |
Maruyama, Kobayashi, Katsura, & Kuriki |
Initial behavior of the optokinetic response elicited by transparent stimuli |
| 170 |
Loschky, McConkie, Yang, & Miller |
The effects of eccentricity-dependent image filtering on saccade targeting in natural images |
| 171 |
Liston, Carello, & Krauzlis |
Speed-accuracy tradeoffs for pursuit and saccades in a luminance discrimination task |
| 172 |
Kveraga, Boucher, & Hughes |
Learning to look the other way |
| 173 |
Kaiser & Lappe |
Perisaccadic compression of space orthogonal to saccade direction |
| 174 |
Haushofer, Schiller, Kendall, Slocum, & Tolias |
Express saccades: the conditions under which they are realized and the brain structures involved |
| 175 |
Hafed & Clark |
Pre-saccade target color influences the perception of its post-saccade counterpart |
| 176 |
Garbade & Deubel |
Mechanisms of smooth pursuit eye movements after pursuit initiation |
| 177 |
Fujita & Amagai |
Position-dependent gain adaptation of human horizontal saccades using the double step paradigm |
| 178 |
Chukoskie & Movshon |
Visual responses of MT neurons during smooth pursuit eye movements |
| 179 |
Berryhill, Boucher, Kveraga, & Hughes |
Latency of smooth pursuit under conditions of stimulus-response uncertainty |
| 180 |
Miles, Masson, & Yang |
Velocity tuning of short-latency version and vergence eye movements in humans: dynamical limits set by retinal image speed |
| 181 |
Masson, Yang, & Miles |
Reversed phi motion elicits reversed ocular following at short-latency |
| 182 |
Amso, Slemmer, & Johnson |
Visual attention mechanisms are sensitive to manner of occlusion |
| 183 |
Zur & Ullman |
Measuring and modeling filling-in effects in retinal AMD scotomas |
| 184 |
Westover, Anderson, & David C. Van Essen |
A combined signals and neurobiological model for predicting P and M ganglion cell responses |
| 185 |
Thorn, Thorn, He, Held, & Gwiazda |
How do optical aberrations and defocus affect retinal images? |
| 186 |
Petry & Lu |
Improved temporal vision after a color deprivation paradigm: Correlates in retinal ganglion cells |
| 187 |
Makous |
Serial stages of gain control |
| 188 |
Yuan, Reinach, Sun, & Yuan |
The study of contrast sensitivity and color vision of the Yellow colored (UVCY) Intraocular Len |
| 189 |
Yu, Klein, & Levi |
On collinear flanker facilitation of contrast detection |
| 190 |
Simpson, Findlay, & Manahilov |
An ideal observer approach to simple visual reaction time |
| 191 |
Verghese |
Self-cueing contributes to contour detection in noise |
| 192 |
Tani & Sato |
The spatial frequency characteristics of the Cafe wall illusion |
| 193 |
Talgar & Carrasco |
Covert transient attention does not change the characteristics of a spatial frequency channel |
| 194 |
Stephens & Dannemiller |
Decruitment effects for magnitude estimates of pattern contrast |
| 195 |
Skoczenski & Soffer |
Orientation tuning of vernier acuity in human infants and adults |
| 196 |
Samonds, Allison, Brown, & Bonds |
Spike train analysis reveals cooperation between Area 17 neuron pairs that enhances fine discrimination of orientation |
| 197 |
Sally, Gurnsey, & Poirier |
Orientation discrimination in foveal and extra-foveal vision: Measuring contrast sensitivity |
| 198 |
Sakaguchi |
Contrast dependency of orientation filling-in |
| 199 |
Rudd & Zemach |
Contrast, assimilation, and neural edge integration |
| 200 |
Rovamo & Melmoth |
Scaling of both gratings size and contrast is necessary for equalising detection across eccentricities |
| 201 |
Purves & Yang |
The Poggendorff illusion explained by the statistics of natural scene geometry |
| 202 |
Ozgen, Sowden, & Schyns |
Flexible scale use is retinotopically specific |
| 203 |
Olzak & Laurinen |
Models of lateral interactions: A failure to generalize |
| 204 |
McAnany & Levine |
The vanishing disk; a revealing quirk of the scintillating grid illusion |
| 205 |
Mareschal & Shapley |
Effects of contrast on spatial binding and resolution |
| 206 |
Mancini, Gurnsey, & Sally |
Effects of frequency content on the detection of anti-symmetry |
| 207 |
Langley & Atherton |
A de-noising model of contrast adaptation to explain contrast perception |
| 208 |
Johnston, Timney, Leung, & Khan |
Alcohol reduces simultaneous contrast effects in human vision |
| 209 |
Hardy & De Valois |
Hue-selective elevation in luminance contrast detection threshold following adaptation to luminance-varying gabor patches |
| 210 |
Gurnsey, Sally, & Ball |
Equating the "visibility" of luminance- and contrast-modulations |
| 211 |
Gaspar, Bennett, & Sekuler |
Isolating the causes of internal noise |
| 212 |
Francis |
Developing a new quantitative account of backward masking |
| 213 |
Felisberti & Morgan |
Effects of suprathreshold contrast modulation on crowding |
| 214 |
Leykin & Cutzu |
Distinguishing paintings from photographs |
| 215 |
Clifford, Spehar, Solomon, Martin, & Zaidi |
Colour-luminance interactions in human orientation perception |
| 216 |
Chong & Treisman |
Representation of statistical properties |
| 217 |
Chen & Tyler |
Lateral modulation of contrast discrimination: Flanker orientation and location effects |
| 218 |
Carney, Hill, Marathe, Sy, Lin, & Chen |
WinVis – a novel approach to designing software for psychophysical experiments |
| 219 |
Bredfeldt & Ringach |
Dynamics of spatial frequency tuning of macaque LGN |
| 220 |
Bonnar, Gosselin, & Schyns |
Revealing and suppressing the visual information for recognition |
| 221 |
Anzai, Van Essen, Peng, & Hegde |
Receptive field structure of monkey V2 neurons for encoding orientation contrast |
| 222 |
Anderson, Murphy, & Jones |
Center-surround effects on orientation discrimination with visual noise stimuli |
| 223 |
Allen, Hess, Dakin, & Mansouri |
Spatial integration of second-order orientation |
| 224 |
Dixon, Myles, Smilek, Zanna, & Merikle |
Synaesthetic photisms and context |
| 225 |
Rainville & Makous |
The temporal mechanisms mediating synchrony perception |
| 226 |
Motoyoshi |
Visual pattern synchrony as mediated by spatial interactions |
| 227 |
Ichikawa |
Visual simultaneity is affected by stimulus depth |
| 228 |
Huk, Palmer, & Shadlen |
Temporal integration of visual motion information: Evidence from response times |
| 229 |
Henning, Wichmann, & Bird |
Pulse train detection and discrimination in pink noise |
| 230 |
Heinrich, Aertsen, & Bach |
Striking Gestalt modulates EEG gamma activity - but not in accordance with the temporal binding hypothesis |
| 231 |
Eagleman, Jacobson, & Sejnowski |
The perceived brightness of a flash can be influenced by temporal properties of its neighbors |
| 232 |
Cohn & Nguyen |
Turning it on piecemeal makes it seen faster |
| 233 |
Blake & Lee |
Temporal precision of visual grouping from temporal structure |
| 234 |
Zabulis & Backus |
The starry night texture and its use to isolate depth cues |
| 235 |
Potechin, Gurnsey, & Sezikeye |
The central performance drop can be elicited without a backward mask |
| 236 |
Atherton, Hinds, & Langley |
Orientation-texture-defined edges: a computational model |
| 237 |
Prins & Kingdom |
Orientation- and frequency-modulated textures at low depths of modulation are processed by off-orientation and off-frequency texture mechanisms |
| 238 |
Suganuma & Yokosawa |
Is multiple object tracking affected by three-dimensional rigidity? |
| 239 |
Slemmer & Johnson |
Object tracking in ecologically valid occlusion events |
| 240 |
Leonard, Pylyshyn, Cohen, & Dennis |
The effect of a secondary monitoring task on Multiple Object Tracking |
| 241 |
Dennis & Pylyshyn |
Effect of object discriminability on multiple object tracking |
| 242 |
Ogawa & Yagi |
The processing of untracked objects during multiple object tracking |
| 243 |
Annan & Pylyshyn |
Can indexes be voluntarily assigned in multiple object tracking? |
| 244 |
Triesch, Sullivan, Hayhoe, & Ballard |
Transient visual representations: a change blindness approach |
| 245 |
Rensink |
Failure to see more than one change at a time |
| 246 |
Marois, Todd, & Chun |
The impact of reaching visual short-term memory capacity on the attentional blink |
| 247 |
Moore & Lleras |
Object substitution masking and object-token individuation |
| 248 |
Scholl & Feldman |
The temporal dynamics of object formation in object-based attention |
| 249 |
Pylyshyn |
Tracking multiple identical moving objects: Analysis of recent findings |
| 250 |
Li, VanRullen, Koch, & Perona |
Detection of objects in natural scenes with minimal or no attention |
| 251 |
Hollingworth & Henderson |
Sustained insensitivity to incremental scene rotation: A dissociation between explicit change detection and visual memory |
| 252 |
DiMase, Oliva, & Wolfe |
Taking a picture apart: Memory for backgrounds and objects in scene photographs |
| 253 |
Christou & Thornton |
Boundary extension as a function of viewpoint in a virtual scene |
| 254 |
Epstein, Graham, Kanwisher, & Downing |
Scene representations in the parahippocampal place area are viewpoint-specific |
| 255 |
Walker & Malik |
When is scene recognition just texture recognition? |
| 256 |
Sperling, Lyu, & Kim |
Motion standstill in first- and second-order motion |
| 257 |
Cormack & Stevenson |
Illusory reverse-motion from contrast modulation |
| 258 |
Lindsey, Denys, Brown, & Orban |
fMRI correlates of isoluminant motion perception |
| 259 |
Burr & Ross |
Direct evidence that 'speedlines' aid perception of motion direction |
| 260 |
Shim & Cavanagh |
Illusory displacement of flash location depends on the perceived direction of bistable quartet motion |
| 261 |
Melcher & Morrone |
Retinotopic temporal integration of motion across saccadic eye movements |
| 262 |
Enns |
Illusory feature binding in the standing wave illusion |
| 263 |
Paul & Schyns |
Attention modulates perceptual asynchrony in binding |
| 264 |
Arnold & Clifford |
Temporal dynamics of colour and motion perception |
| 265 |
Ramachandran, Hubbard, & Butcher |
"Higher" and "lower" forms of synesthesia may arise from cross-wiring at different cortical stages |
| 266 |
Butcher, Hubbard, & Ramachandran |
Top-down influences affect the experience of synesthetically induced colors |
| 267 |
Merikle, Smilek, & Dixon |
Synaesthetic photisms and memory |
| 268 |
Brockmole, Wang, & Irwin |
Properties of memory-percept integration |
| 269 |
Becker & Pashler |
Volatile visual representations |
| 270 |
Vogel, Woodman, & Luck |
The rapid time-course of visual working memory consolidation |
| 271 |
Angelone & Levin |
Visual short-term memory load and detecting feature changes |
| 272 |
Luck, Woodman, Schmidt, Vogel, & Vecera |
The effects of attentional capture on visual working memory |
| 273 |
Alvarez & Cavanagh |
The capacity of visual short-term memory is set by total information load, not number of objects |
| 274 |
Motter |
Crowding and object integration within the receptive field of V4 neurons |
| 275 |
Rolls, Aggelopoulos, & Zheng |
Reduced receptive field size of inferior temporal cortex neurons and reduced effects of attention when objects are selected in natural scenes |
| 276 |
Battelli & Cavanagh |
Bilateral deficit of transient visual attention in neglect |
| 277 |
Riddoch & Humphreys |
Between-object action coupling influences visual selection: Neuropsychological evidence |
| 278 |
Bonneh, Pavlovskaya, & Soroker |
Slow binocular rivalry in hemispatial neglect |
| 279 |
Legge, Lee, Owens, Cheung, & Chung |
Visual span: A sensory bottleneck on reading speed |
| 280 |
Beaudot & Mullen |
Orientation selectivity in luminance and color vision assessed using 2-d bandpass filtered spatial noise |
| 281 |
Scharff & Ahumada |
Identification of filtered letters in filtered noise |
| 282 |
Baldassi & Verghese |
Effects of cueing on the tuning function for orientation |
| 283 |
Sowden, Ozgen, & Schyns |
When a plaid is not a plaid: attentional modulation of spatial frequency processing |
| 284 |
Levi & Klein |
Noise provides new signals about the spatial vision of amblyopes |
| 285 |
Tse, Smith, Augath, Trinath, Logothetis, & Movshon |
Using Glass Patterns and fMRI to identify areas that process global form in macaque visual cortex |
| 286 |
Read, Cumming, & Parker |
Simple cells can show non-linear binocular combination |
| 287 |
Cumming |
Receptive field structure and disparity tuning in primate V1 |
| 288 |
Hayashi, Maeda, Tachi, & Shimojo |
A computational model of stereopsis that produces depth from interocularly unpaired points as well as binocular rivalry |
| 289 |
Albert & Nakayama |
Stereo thresholds for binocularly-matched opposite-contrast edges are close to those for same-contrast edges |
| 290 |
McKee & Norcia |
Dynamic topography of the response to monocular and binocular misalignment |
| 291 |
Vreven, Verghese, & McKee |
Configuration effects in the stereoprocessing of 3D surfaces |
| 292 |
Yoshida, Ashida, & Osaka |
Capacity of short term implicit memory is larger than visuospatial working memory in visual search |
| 293 |
Wilken & Mattingley |
Capacity limits in the detection and identification of change have implications for models of visual short term memory |
| 294 |
Saiki |
Motion severely reduces capacity and life of object visual working memory |
| 295 |
Reinecke & Wolfe |
Serial position effects in visual short term memory |
| 296 |
Zhang, Berends, Tanaka, & Schor |
Parafoveal limits of simultaneous and sequential stereo-slant discrimination |
| 297 |
Watt, Banks, Ernst, & Zumer |
Screen cues to flatness do affect 3d percepts |
| 298 |
Watamaniuk & Van Oss |
3-D Structure in global flow stimuli |
| 299 |
Schlerf & Domini |
Role of 3D shape in contrast detection of luminance gratings |
| 300 |
Rosas, Wichmann, & Wagemans |
Surface-slant-from-texture discrimination: Effects of slant level and texture type |
| 301 |
Peuskens, Todd, Norman, Van Hecke, & Orban |
Neural correlates of judging 3D structure from motion |
| 302 |
Nawrot, Bell, & Agarwal |
Eye movements and lateral translation disambiguate the perceived direction of kinetic depth rotation |
| 303 |
Murray, Olshausen, & Woods |
Processing shape, motion, and three-dimensional shape-from-motion in the human cortex |
| 304 |
Li & Kim |
The effect of a reference on eye-movement-induced distortions of motion-defined shapes |
| 305 |
Interrante, Gorla, Kim, Hagh-Shenas, & Sapiro |
Texture synthesis for 3D shape representation |
| 306 |
Griffiths & Zaidi |
Perceptual asymmetry in solid shape perception |
| 307 |
Emerson & Vaughn |
A mechanism in striate cortex for coding shape from motion |
| 308 |
Champion, Simmons, & Mamassian |
The influence of object size on shape from stereo |
| 309 |
Boyaci & Maloney |
Binocular perception of shape from shading/contour is invariant under ordinal transformations of image intensities |
| 310 |
Bacon, Gosselin, & Mamassian |
Multiple regression reveals 3D internal surface representations |
| 311 |
Atherton, Amiri, Zhuang, Hu, He, & Yonas |
Cortical responses to layout change specified by two pictorial cues: An fMRI study |
| 312 |
Zhao & Farell |
The binocular neural mechanism: gnostic and population coding |
| 313 |
Zalevski, Hill, & Henning |
The effect of disparity/vertical-scaling conflict in a stereoacuity task |
| 314 |
Whitaker & Pardhan |
Binocular contrast detection in the peripheral field in young and older subjects |
| 315 |
Wallace & Mamassian |
Efficiency of stereoscopic transparency |
| 316 |
Visco & Stevenson |
Lateral interactions modify the Pulfrich effect |
| 317 |
Tanaka, Zhang, Berends, & Schor |
Temporal masking of stereo-slant discrimination |
| 318 |
Pardhan & Whitaker |
Contrast and orientation dependence on binocular recognition summation in the periphery |
| 319 |
Yanagisawa & Uchikawa |
Contrast adaptation effects under interocualr suppression for normal and strabismic observers |
| 320 |
Li & Farell |
Interactions among stereo channels of different scales |
| 321 |
Lee & Dobbins |
Stereo fusional limit and Panum's limiting case revisited using dichoptic color fusion |
| 322 |
Lee, Shioiri, & Yaguchi |
The spatiotemporal frequency property of stereopsis |
| 323 |
Kaiser & Sweet |
Visual cues for closed-loop control |
| 324 |
Howe & Grossberg |
A laminar cortical model of monocular and binocular interactions in depth perception |
| 325 |
Hillis, Banks, & Landy |
How are texture and stereo used in slant discrimination? |
| 326 |
Ghose, Banks, & Hillis |
Eye dominance changes with eye position and image magnification |
| 327 |
Ding & Sperling |
A gain-control theory of binocular combination |
| 328 |
Buckthought & Stelmach |
Spatial scale interactions in stereopsis for different types of band-limited stimuli |
| 329 |
Brooks & Stone |
Monocular artifacts and the perception of stereomotion speed |
| 330 |
Bradshaw, Elliot, & Luffman |
The importance of binocular cues in the on-line control of prehension |
| 331 |
Wood, Owens, Woolf, & Owens |
Predicting night-time visibility while driving |
| 332 |
Vaina & Giese |
Biological Motion: why some motion impaired stroke patients "can" while others "can't" recognize it? A computational explanation. |
| 333 |
Shipley |
The role of objects and events in the perception of biological motion |
| 334 |
Shiffrar & Pinto |
Are we visual animals? |
| 335 |
Pinto, Parke, & Shiffrar |
Change mindfulness: Attention to human movement |
| 336 |
Paterson, Pollick, & Ude |
Shaping Biological Motion: Adding realistic form cues to biological motion displays |
| 337 |
Fujimoto & Sato |
Motion induction by biological motion |
| 338 |
Jacobs, Pinto, & Shiffrar |
Frequency, context, and human motion perception |
| 339 |
Hiris & Cowan |
Detecting point light walkers within masks: Influence of orientation, translation, and location |
| 340 |
Harrison, Fisher, & Booth |
Perception and categorization of computer animated walking figures |
| 341 |
Grossman & Blake |
An investigation of neural activity associated with viewing point-light animal, face and hand movements |
| 342 |
Cohen, Shipley, & Pinto |
The role of experience in the perception of biological motion |
| 343 |
Xing & Ahumada |
Estimation of human-observer templates in temporal-varying noise |
| 344 |
Shimozaki, Eckstein, & Abbey |
Classification images for a cueing paradigm with 100% valid simultaneous cues: Evidence for attentional leaking |
| 345 |
Sauer, Andersen, & Saidpour |
Detection of collision objects travelling on curved paths |
| 346 |
Santiago, Chouchourelou, Jacobs, Danatzko, Dagan, Cohen, & Shiffrar |
Recognition of objects and actions |
| 347 |
Saidpour & Andersen |
Use of Speed Information in Detecting Collision Events |
