| 1 |
Saunders & Knill |
Response to perturbations of visual feedback during reaching movements |
| 2 |
Andersen, Hahn, & Saidpour |
Static scene information and the perception of locomotion |
| 3 |
Crowell, Todd, & Bingham |
Distinct perceptual representations for visually-guided reaches |
| 4 |
Durgin, Fox, & Kane |
Visual contributions to locomotor recalibration |
| 5 |
Ooi, May, Gunther, & He |
Prism adaptation effects on absolute distance judgment |
| 6 |
Glennerster, Hansard, & Fitzgibbon |
How could ego-centric location be defined neurally? |
| 7 |
Mitroff & Simons |
A lack of confidence in implicit change detection |
| 8 |
Beck & Levin |
The role of beliefs about intention in producing change blindness blindness |
| 9 |
Vogel & Luck |
Quartering the spotlight: Spatial properties of selective storage in visual working memory |
| 10 |
Levin |
Visual metacognitions underlying change blindness blindness and estimates of picture memory |
| 11 |
Angelone & Levin |
Change blindness and modes of processing: Are representation and comparison independent? |
| 12 |
Wayand & Levin |
Ignoring a merciless act |
| 13 |
Silverman & Mack |
Priming from change blindness |
| 14 |
Murakami |
The flash-lag effect in random motion reveals distributed differential latency between the flash and motion |
| 15 |
Watanabe, Nijhawan, & Shimojo |
Position capture by object motion through a slit |
| 16 |
Eagleman & Sejnowski |
The flash-lag illusion: distinguishing a spatial from a temporal effect, and why that matters for interpreting visual physiology |
| 17 |
Stoet & Snyder |
Task preparation in monkeys |
| 18 |
Rossi, Bichot, Desimone, & Ungerleider |
Top-down, but not bottom-up: Deficits in target selection in monkeys with prefrontal lesions |
| 19 |
Priebe, Cassanello, & Lisberger |
The speed tuning of single units in macaque visual area MT depends on spatial form and contrast |
| 20 |
Droll, Bisley, & Pasternak |
The delay activity of some MT neurons may signal the remembered direction of motion |
| 21 |
Bilodeau & Cavanagh |
Disintegration of shapes in peripherally viewed rotating displays |
| 22 |
Lindner, Haarmeier, & Thier |
Motion perception during smooth pursuit eye movements: object and background motion perception depend on different non-retinal signals on eye velocity |
| 23 |
Anderson, Wu, & Dobkins |
Tuning of infant directional mechanisms |
| 24 |
Aslin, Blake, & Chun |
A dissociation in the transfer of perceptual learning based on visual temporal structure |
| 25 |
Slemmer, Kirkham, & Johnson |
Visual statistical learning in infancy |
| 26 |
Mednick, Luskin, Cantero, Atienza, Nakayama, & Stickgold |
Napping necessary for within-day perceptual learning |
| 27 |
Liu, Lu, & Qian |
Learning motion discrimination without MT |
| 28 |
Abbey, Eckstein, & Shimozaki |
The efficiency of perceptual learning in a visual detection task |
| 29 |
Koyama, Harner, & Watanabe |
Different mechanisms for the learning of motion detection vs. the learning of motion direction discrimination |
| 30 |
Sa'ry, Xu, Shostak, Royal, Schall, & Casagrande |
Behavioral relevance influences LGN neurons of macaque monkey in the absence of receptive field stimulation |
| 31 |
Roelfsema & Spekreijse |
The representation of erroneously perceived stimuli in the primary visual cortex |
| 32 |
Lamme, Zipser, & Spekreijse |
Masking interrupts figure-ground signals in V1 |
| 33 |
Boynton |
Orientation-specific pattern adaptation measured with event-related fMRI |
| 34 |
Touryan, Lau, & Dan |
Nonlinear analysis of complex cells in cat visual cortex |
| 35 |
Smith, Bair, Cavanaugh, & Movshon |
Latency of inhibition from inside and outside the classical receptive field in macaque V1 neurons |
| 36 |
Yen & Gray |
Properties of contour integration in a macaque monkey |
| 37 |
Rubin & Albert |
Real-world scenes can be easily recognized from their edge-detected renditions: Just add motion! |
| 38 |
Vessel, Biederman, Lee, & Subramaniam |
Contour grouping into L-vertices depends on contrast polarity: Evidence for the incorporation of image statistics into mechanisms of perceptual grouping |
| 39 |
Koenderink, van Doorn, Kappers, & Todd |
Physical and mental viewpoints in pictorial relief |
| 40 |
Todd & Oomes |
The perception of 3D shape from surface contours |
| 41 |
Sauer, Braunstein, Andersen, & Bian |
Judged shape of ground plane regions in realistic 3-D scenes |
| 42 |
Sinha & Torralba |
Role of low-level mechanisms in brightness perception |
| 43 |
Fleming, Dror, & Adelson |
Surface reflectance estimation under unknown natural illumination |
| 44 |
Zdravkovic & Gilchrist |
Anchoring illumination |
| 45 |
Gilchrist |
Recent applications of the anchoring approach |
| 46 |
Gosselin, Bonnar, Paul, & Schyns |
"Superstitious" perceptions to depict pure internal object representations |
| 47 |
Koning & van Lier |
Differential effects of 2-D versus 3-D connectedness on object transformations |
| 48 |
Lotto & Purves |
An empirical explanation of the Chubb Illusion |
| 49 |
Herzog & Fahle |
First is best |
| 50 |
Grossberg |
How visual percepts emerge from complementary brain dynamics |
| 51 |
Hill |
An investigation of bootstrap interval coverage and sampling efficiency in psychometric functions |
| 52 |
Murray, Bennett, & Sekuler |
No pointwise nonlinearity in shape discrimination |
| 53 |
Shimojo & Kamitani |
Fillin-in induced by high-contrast edge adaptation |
| 54 |
Chong & Treisman |
Representation of statistical properties |
| 55 |
Palomo & Watanabe |
Competitive recruitment in visual form representation |
| 56 |
Suzuki & Grabowecky |
Rapid temporal coincidence of spatially separated shapes can be resolved using sustained emergent percepts |
| 57 |
Hurvich |
Some little known aspects of Ewald Hering's scientific contributions |
| 58 |
Shady & MacLeod |
Desaturation of gratings and flicker near and above the resolution limit |
| 59 |
Brown & Lindsey |
The color blue: A psychophysical explanation for a linguistic phenomenon |
| 60 |
Purves & Lotto |
Explanation of some major features of color perception |
| 61 |
Troscianko, Parraga, & Tolhurst |
Is color vision good for picking fruit? |
| 62 |
Longere, Kraft, & Brainard |
Bayesian model of human color constancy |
| 63 |
Fine & MacLeod |
Visual segmentation based on the luminance and chromaticity statistics of natural scenes |
| 64 |
Buchsbaum & Tailor |
The elementary structure of natural color images and its possible neurophysiological correlates |
| 65 |
Caywood, Willmore, & Tolhurst |
The color tuning of independent components of natural scenes matches V1 simple cells |
| 66 |
Blake, Palmeri, Marois, & Whetsell |
Visual binding of synesthetic colors to achromatic forms |
| 67 |
Ramachandran & Hubbard |
Neural cross wiring and synesthesia |
| 68 |
Poggel, Kasten, Mueller-Oehring, & Sabel |
Focusing attention on the visual field border: Short-term and long-term effects of visuo-spatial cueing in patients with visual field defects |
| 69 |
Lleras & Moore |
Attentional modulation of Troxler fading |
| 70 |
Yeshurun & Levy |
The effects of spatial attention on temporal resolution |
| 71 |
Michael, Boucart, Degreef, & Leys |
The thalamus interrupts top-down attentional control |
| 72 |
Chen |
On perceptual load, size of the attentional window, and distractor interference |
| 73 |
Siegel, Phinney, Turner, & Jando |
Topographic map for visual space in association parietal cortex of behaving monkey |
| 74 |
Carrasco & Loula |
Effects of selective adaptation on texture segmentation and its interaction with covert attention. |
| 75 |
Levi, Klein, & Hariharan |
Foveal crowding is just "good old" contrast masking, but peripheral crowding is more |
| 76 |
Talgar & Carrasco |
The effects of attention in texture segmentation in the lower and upper visual fields |
| 77 |
Atchley, Grobe, & Fields |
The effect of smoking on sensory and attentional masking |
| 78 |
Cameron, Tai, & Carrasco |
Effects of transient covert attention on the psychometric function |
| 79 |
Williams, Yeshurun, & Carrasco |
Masked or not, covert attention enhances spatial resolution: Support for signal enhancement |
| 80 |
Paul, Giaschi, Cavanagh, & Cline |
Attention deficits in children with anisometropic amblyopia |
| 81 |
Schneider & Bavelier |
Exogenous cueing and visual latency: attention, response bias or sensory facilitation? |
| 82 |
Tse, Sheinberg, & Logothetis |
Spatial attention elongates both toward and away from an exogenous flash |
| 83 |
Eckstein, Shimozaki, & Abbey |
The footsteps of attention in the Posner paradigm revealed by classification images |
| 84 |
Tsuchiya, Rees, Braun, & Koch |
Attentional modulation of visual motion perception using novel wavelet stimuli |
| 85 |
Sohn, Vidnyanszky, Blaser, & Papathomas |
Attention to one component of bivectorial transparent motion strongly inhibits the processing of the unattended component |
| 86 |
Alais |
Motion repulsion: Effects of noise and attention |
| 87 |
Tsujimura & Zaidi |
Higher sensitivity for relative motion is due to position tracking |
| 88 |
Del Vecchio, von Grunau, & Faubert |
Attentional selection of first- and second-order motion stimuli |
| 89 |
Rezec & Dobkins |
Sensory- and attention- based visual field asymmetries for motion and orientation discrimination |
| 90 |
Reeves & DeCaro |
The visual recognition of rotated shapes |
| 91 |
Nilson, Joneleit, Smith, & Hoffman |
Color and part |
| 92 |
Nederhouser & Mangini |
A translation between S1 and S2 eliminates costs of changes in the direction of illumination in object matching |
| 93 |
Hunt & J.Bassi |
The effects of blur on neuropsychological tests in young and old adults |
| 94 |
Young & Wasserman |
Visual variability discrimination in the pigeon is not determined by spatial regularity |
| 95 |
Pins, Boucart, Meyer, & Jack |
Automatic object identification in a peceptual matching paradigm : An fMRI study |
| 96 |
Bravo & Farid |
Top-down and bottom-up processes for object segmentation |
| 97 |
Wagemans, Panis, De Winter, & Op de Beeck |
Perceptual and conceptual priming in picture identification on the basis of contour fragments with specific curvature properties |
| 98 |
Graf |
Analog topological transformations in basic level object recognition |
| 99 |
Coltheart, Mondy, & Moore |
Effects of repetition on the report of RSVP sequences of familiar and novel objects |
| 100 |
MacKeben |
Enhancement of peripheral letter recognition by modifying typographic features |
| 101 |
Zaenen, Wagemans, & Vogels |
Learning to discriminate highly similar three-dimensional objects: Qualitative versus quantitative differences and viewpoint (in)dependency |
| 102 |
Takarae & Levin |
Is the pen mightier than the pen-axe? Correct and incorrect conjunctions of parts in visual search for everyday objects |
| 103 |
Woodman & Luck |
Serial deployment of attention during visual search |
| 104 |
Franconeri & Simons |
Disoccluding and looming objects capture attention |
| 105 |
Rauschenberger & Yantis |
What counts as an object in the new-object hypothesis of attentional capture? |
| 106 |
Maljkovic |
Short-term priming for segmenting features modulates attentional capacity and results in dynamic shift of the locus of selection |
| 107 |
McCarley, Kramer, Scialfa, & Colcombe |
Attentional priming in visual search: Age-based differences in feature priming |
| 108 |
Leber & Egeth |
Exploring mode selection in visual search |
| 109 |
Horowitz & Thornton |
Efficient memory for targets in visuomotor sequential search task |
| 110 |
Seiffert & Treisman |
Target recognition in visual search |
| 111 |
Folk, Remington, Lachter, & Ruthruff |
Top-down gating of preattentive featural processing in multidimensional objects |
| 112 |
Palix, Viaud-Delmon, Michel, & Leonards |
Cortical dynamics of attention during visual search: An event-related potential study |
| 113 |
Kontsevich |
Serial search is certainly serial |
| 114 |
Kristjansson, Wang, & Nakayama |
The role of priming in conjunction search |
| 115 |
Sheth & Shimojo |
Color and orientation pop-outs differentially affect discrimination |
| 116 |
Yokoi & Uchikawa |
Categorical color perception influences heterochromatic visual search |
| 117 |
Donnelly, Parton, & Usher |
Detecting contour targets amongst temporally segmented and non-segmented distractors |
| 118 |
Davis, Shikano, Peterson, Keyes, & Shook |
An SDT psychophysical approach to visual search and divided attention |
| 119 |
Carlson & Shomstein |
Disambiguating strategic effects in visual search |
| 120 |
Baldassi & Verghese |
Effect of attention on a search task with orientation noise |
| 121 |
Butcher, Oliva, & Wolfe |
Things fall apart: The transience of binding in visual search |
| 122 |
Ostrovsky & Sinha |
The role of 3D perspective in visual search |
| 123 |
Oliva, Wolfe, & Arsenio |
Memory as an internal vision |
| 124 |
Sanocki, Sellers, & Mittelstadt |
High-capacity visual short term memory for layout |
| 125 |
Xu |
Limitations in object-based feature encoding in visual short-term memory |
| 126 |
Rensink |
Grouping in visual short-term memory |
| 127 |
Cai & Schlag |
A new form of illusory conjunction between color and shape |
| 128 |
Landman, Spekreijse, & Lamme |
A neural correlate of change blindness in V1 |
| 129 |
Cavanagh & Barton |
Lights from beyond the visual field are not seen |
| 130 |
Tong & Engel |
Interocular rivalry revealed in the human cortical blind-spot representation |
| 131 |
Kreiman, Fried, & Koch |
Single neuron responses in humans during binocular rivalry and flash suppression |
| 132 |
Gray |
How do baseball batters use "where" and "when" information? |
| 133 |
Vishton, Tokuda, Simons, & Cutting |
Differential use of high spatial frequency information for heading perception judgment and heading-mediated driving |
| 134 |
Kearns, Warren, Tarr, & Duchon |
Does optic flow contribute to human path integration? |
| 135 |
Cunningham, Kreher, von der Heyde, & Buelthoff |
Do cause and effect need to be temporally continuous? Learning to compensate for delayed vestibular feedback |
| 136 |
Readinger, Chatziastros, Cunningham, Cutting, & Buelthoff |
Gaze-eccentricity effects on automobile driving performance - or - Going where you look |
| 137 |
Harrison, Warren, & Tarr |
The geometry of "cognitive maps": Metric vs. ordinal structure |
| 138 |
Hall & Philbeck |
Do we update locations more poorly as they pass behind us? |
| 139 |
Grosjean & Mordkoff |
On the influence of motor preparation on perceptual processing |
| 140 |
Cohn, Han, & Van |
How a mouse can gauge the quality of inaction |
| 141 |
Creem |
Spatial updating after imagined self and object movement: translation is similar to rotation |
| 142 |
Flückiger, Baumberger, & Cutting |
Virtual driving performances from different eye-heights |
| 143 |
Kopinska & Harris |
Perceptual space coded in body coordinates |
| 144 |
Sibigtroth & Banks |
Vestibular stimulation in heading estimation |
| 145 |
Maonsson |
Suppressive mechanisms in contour integration |
| 146 |
Kovacs, Lukacs, Feher, Racsmany, & Pleh |
Contour integration deficit in Williams Syndrome children |
| 147 |
Beaudot |
Temporal asynchrony in contour integration: A retelling of the fable of "The Hare and the Tortoise" |
| 148 |
Popple & Li |
Testing a V1 model --- Perceptual biases and saliency effects |
| 149 |
Li & Zaidi |
Phase spectra are irrelevant in 3D shape from natural textures |
| 150 |
Motoyoshi & Nishida |
Spatiotempoal interaction in detection of texture orientation modulations |
| 151 |
Maddess & Nagai |
Discriminating isotrigon textures |
| 152 |
Wilson, Switkes, & De Valois |
Effects of contrast variations on the perception of glass patterns |
| 153 |
Rainville & Makous |
The spatial tuning of perceived temporal synchrony |
| 154 |
Griffiths & Zaidi |
Looking through Ames' window |
| 155 |
Benton, Johnston, & McOwan |
Computational modeling of non Fourier motion |
| 156 |
Scott-Samuel & Hess |
What does the Ternus display tell us about motion processing in human vision? |
| 157 |
Hupé & Rubin |
Dynamics of bi-stable perception of plaids |
| 158 |
Lankheet |
Spatiotemporal tuning of motion coherence detection in cats. |
| 159 |
Ashida & Yamagishi |
Movement-related positional bias for luminance and colour motion |
| 160 |
Meese & Anderson |
Spiral mechanisms are required to account for summation of complex motion components |
| 161 |
Vidnyanszky, Blaser, & Papathomas |
An explanation for unidirectional motion aftereffects following adaptation to bivectorial transparent motion |
| 162 |
Verstraten & van Wezel |
Nulling the motion aftereffect of transparent motion |
| 163 |
Lappin, Tadin, & Gaddy |
Detecting spatial patterns of motion energy |
| 164 |
Punzel, Yonas, & Schacter |
Grouping and detection of global apparent motion |
| 165 |
Mukai, Hibino, & Watanabe |
The likelihood of motion capture is more strongly determined by the degree of color contrast of adjacent gratings than by the degree of luminance contrast |
| 166 |
Yu & Craft |
Do barriers influence motion correspondence? |
| 167 |
Thomas, Cumming, & Parker |
Modelling the relative disparity selectivity of V2 neurons |
| 168 |
Li |
Modeling pre-attentive stereo grouping by intracortical interactions in early visual cortex |
| 169 |
Zucker |
Hypercolumn-based stereo correspondence |
| 170 |
Ono, Mapp, & Howard |
The cyclopean eye in vision: The new and old data continue to hit you right between the eyes |
| 171 |
Erkelens & van Ee |
Evidence for two binocular colour mechanisms |
| 172 |
Bridge, Cumming, & Parker |
Psychophysical evidence against the use of orientation disparity in the perception of slant. |
| 173 |
Sobel & Blake |
Does context influence a rival target's escape from suppression? |
| 174 |
Ito & Sato |
The chromatic contribution to the human stereo system measured with a depth-canceling technique |
| 175 |
Adams & Mamassian |
Bayesian slant estimation |
| 176 |
Wichmann, Willems, Rosas, & Wagemans |
Perception of planar shapes in depth |
| 177 |
Wilcox & Duke |
Spatial scaling of 3D surface interpolation |
| 178 |
Hillis & Banks |
Slant adaptation improves slant discrimination |
| 179 |
Backus & Nolt |
Analysis of stereoscopic metamers |
| 180 |
Forte, Peirce, & Lennie |
Binocular integration of partially occluded surfaces |
| 181 |
Likova, Kontsevich, & Tyler |
Providing disparity curvature dramatically enhances localization of sampled luminance profiles |
| 182 |
Craft & Yu |
"Misperception" of stereoscopic structure |
| 183 |
Lee & Stelmach |
Stereoscopic depth perception at high velocities |
| 184 |
Warren, Fajen, & Belcher |
Behavioral dynamics of steering, obstacle avoidance, and route selection |
| 185 |
Wann & Swapp |
Where do we look when we steer and does it matter? |
| 186 |
Foo, Duchon, Warren, & Tarr |
Do humans integrate routes into a "cognitive map"? |
| 187 |
Fajen & Warren |
Interception of moving objects on foot |
| 188 |
von der Heyde, Riecke, Cunningham, & Bülthoff |
No visual dominance for remembered turns - Psychophysical experiments on the integration of visual and vestibular cues in virtual reality |
| 189 |
Stankiewicz, Legge, & Schlicht |
The effect of layout complexity on human and ideal navigation performance |
| 190 |
Dolomount, Shankar, & Ellard |
Estimating time-to-collision: Further investigations of an animal model. |
| 191 |
Wexler, Lamouret, Panerai, & Droulez |
Self-motion and allocentric criteria in spatial vision |
| 192 |
Bridgeman & Thiem |
Limits of the sensorimotor visual system |
| 193 |
McBeath, Sugar, & Shaffer |
Comparison of active versus passive ball catching control algorithms using robotic simulations |
| 194 |
Culham, DeSouza, Woodward, Kourtzi, Gati, Menon, & Goodale |
Visually-guided grasping produces fMRI activation in dorsal but not ventral stream brain areas |
| 195 |
Matin, Li, Hudson, & Hirsch |
Perceptions of elevation and orientation: From the stimulus basis to the cerebral cortex |
| 196 |
Neri & Heeger |
Spatiotemporal mechanisms of feature detection in human vision |
| 197 |
Pelli, Martelli, & Majaj |
How many channels does it take to integrate features? |
| 198 |
Wu, Kamitani, Maeda, & Shimojo |
Interaction of TMS-induced phosphenes and visual stimuli |
| 199 |
Miller & Kayser |
A model for the development of V1 columnar circuitry |
| 200 |
Brown, Allison, Samonds, & Bonds |
Nonlocal origin of response suppression from stimulation outside the classic receptive field in area 17 of the cat |
| 201 |
Huang, Blau, & Paradiso |
Aspects of human detection and discrimination correlate with macaque V1 physiology |
| 202 |
Bair, Cavanaugh, Smith, & Movshon |
Switching between off and on in the macaque visual system |
| 203 |
Kersten & Schrater |
The tuning of vision to natural contours: Straighter is better |
| 204 |
Adelson & Somers |
Straightness, structure, and shadows |
| 205 |
Kourtzi & Kanwisher |
Processing of perceived shape vs. contours in the human lateral occipital complex |
| 206 |
Ramsden, Hung, & Roe |
Is there a substructure of functional organization for illusory contour processing in V2? |
| 207 |
Kawahara |
Local facilitation of information processing in the attentional blink as indexed by the shooting line illusion |
| 208 |
Mounts, McCarley, Gavett, & Buffan |
Localized attentional inhibition within and between objects |
| 209 |
VanRullen & Koch |
The capacity of visual awareness |
| 210 |
Saiki |
Maintenance and transformation of feature conjunctions in visual working memory in a dynamic situation |
| 211 |
Frieder & Carrasco |
Negative priming for unfamiliar shapes occurs under covert attention |
| 212 |
Gottesman & Gronlund |
The distribution of attention and effects on memory for scene expanse |
| 213 |
Most & Clifford |
Set your sights higher: Category-level attentional effects in the detection of unexpected objects |
| 214 |
Dishon-Berkovits & Treisman |
Feature binding: Competing needs in working memory and long term associative learning? |
| 215 |
Deubel, Wesenick, & Schneider |
Evidence for nevelty pop-out in visual working memory |
| 216 |
Barenholtz & Feldman |
Interpretation of part boundaries and the movement of attention |
| 217 |
Moore, Lleras, & Grosjean |
Perception and action under conditions of inattention |
| 218 |
Lawson, Crewther, Kiely, & Crewther |
Development of the attentional blink in relation to cognitive and short-term memory development |
| 219 |
Yokosawa & Chiba |
Robust midstream order deficit requires change of locations |
| 220 |
Khayat, Spekreijse, & Roelfsema |
Remapping of attentional modulation across eye movements in primary visual cortex of the monkey |
| 221 |
Eccelpoel & Verfaillie |
Incidental vs. deliberate coding of object orientation across eye movements |
| 222 |
May, Flanagan, & Dobie |
OKN, ego vection and motion sickness |
| 223 |
Visco, Stevenson, & Bedell |
Saccades alter perceived duration of full field decrement flashes |
| 224 |
McSorley & Findlay |
Spatial frequency interactions and saccade programming |
| 225 |
Medendorp, Tweed, & Crawford |
Modeling spatial updating during head-free gaze shifts |
| 226 |
Liston & Krauzlis |
Effects of varying visual salience on pursuit and saccade decisions |
| 227 |
Germeys, Panis, & De Graef |
Visual stability across saccades: Transsaccadic memory for location of bystander objects |
| 228 |
Carlson, Covell, & Warapius |
The flexible encoding of a saccade target's features |
| 229 |
McFadden, Shields, & Rounsley |
Local accommodation in a lateral eyed bird facilitates seeing simultaneously in two different places in space |
| 230 |
Aks, Zelinsky, & Sprott |
Memory across eye-movements: 1/f Dynamic in visual search |
| 231 |
Gysen & Verfaillie |
Transsaccadic perception of translating objects |
| 232 |
Grove, Ono, & Kaneko |
The bifixation field as a function of viewing distance |
| 233 |
Niemeier, Crawford, & Tweed |
A probabilistic model of transsaccadic integration |
| 234 |
Dickinson, Calton, & Snyder |
Non-spatial motor-specific activations of two distinct regions of posterior parietal cortex (PPC) |
| 235 |
Mulligan |
Luminance-driven delays measured with the Pulfrich effect and the eye movement correlogram |
| 236 |
Osada & Nagasaka |
The effects of limited eye movements on judgments of emotion of band pass filtered faces |
| 237 |
Chen, Cavanagh, Holzman, & Nakayama |
The cues for smooth pursuit eye movements are different at slow and fast motion |
| 238 |
Edelman, Kristjansson, & Nakayama |
Facilitation of saccade target selection by object centered priming |
| 239 |
Melcher |
The build up of scene memory across eye movements |
| 240 |
Johnston, Clifford, Benton, & McOwan |
Why correlation, energy and gradient motion models are not equivalent |
| 241 |
Quinlan & Culham |
Flicker motion aftereffect produces fMRI activation in MT |
| 242 |
Carlson, Schrater, & He |
Functional imaging of visually expanding motion stimuli: Toward a functional anatomy of visual motion processing |
| 243 |
Gepshtein & Kubovy |
The weights of space and time in the perception of visual motion |
| 244 |
Nichols & Hock |
Counterphase sine gratings flicker at the detection threshold but move above the detection threshold |
| 245 |
Kamiya & Sato |
Motion- and luminance- defined patterns elicit qualitatively same but quantitatively different VEPs |
| 246 |
Mihashi, Shioiri, & Yaguchi |
The size and shape of the receptive field of relative motion detector |
| 247 |
Gilroy & Hock |
Counter-changing contrast as the basis for the perception of contrast-defined, single-element apparent motion |
| 248 |
Cormack & Stevenson |
Exploring motion aliasing under steady illumination |
| 249 |
Geiger, Lorusso, Pesenti, Facoetti, Cattaneo, & Lettvin |
Cross-modal perceptual learning as demonstrated in dyslexics |
| 250 |
Sakano, Kaneko, & Uchikawa |
The effect of haptic learning on the integration of disparity and perspective for the dynamic and static slant perception |
| 251 |
Hairston, Wallace, Stein, Vaughan, & Schirillo |
Cross modal bias occurs with perceptual unity of spatially disparate signals |
| 252 |
Bruno & Bernardis |
Dissociating perception and action in Kanizsa's compression Illusion |
| 253 |
Franz, Thornton, Fahle, & Buelthoff |
Representational momentum in the motor system? |
| 254 |
McConnell, Grudic, Knill, & Kumar |
Reach corrections to unnoticed target perturbations |
| 255 |
Thompson & Dunn |
Pointing at the Judd Illusion |
| 256 |
Hartung, Franz, Kersten, & Buelthoff |
Is the motor system affected by the hollow face illusion? |
| 257 |
Krauzlis & Dill |
Ideal-observer analysis of rostral superior colliculus activity during pursuit and saccade decisions |
| 258 |
Schiller & Tehovnik |
Look and see: How the brain moves your eyes about |
| 259 |
Sommer & Wurtz |
A subcortical source of visual input to the frontal eye field |
| 260 |
Wallman, Khan, Yun, & McFadden |
The spatial scale of attention affects adaptation of saccadic gain |
| 261 |
Hayhoe, Aivar, Mruczek, & Chizk |
Memory for spatial structure in saccadic targeting |
| 262 |
Burr, Ross, & Morrone |
Two systems for spatial location during saccades |
| 263 |
Beutter, Eckstein, & Stone |
Correlated saccadic and perceptual decisions in a visual-search detection task reveal spatial-filter overlap |
| 264 |
Sato, Murthy, Thompson, & Schall |
Effects of perceptual load and response interference on target selection in macaque frontal eye field |
| 265 |
Connolly, Menon, & Goodale |
Areas active during a pointing but not a saccade delay are medial to saccade-and-pointing network |
| 266 |
Bisley & Goldberg |
Spatial attention in the monkey is linked to the location of a planned saccade and can be transiently shifted by a flashed distracter |
| 267 |
Stevenson & Cormack |
Contrast interactions imply a second-order basis for relative disparity discrimination |
| 268 |
Banks |
Disparity scaling and correction for inclined surfaces |
| 269 |
Gillam & Pianta |
Relative and absolute stereo slant |
| 270 |
Bacon & Mamassian |
A look through the crooked window: Depth without binocular correspondence |
| 271 |
Cumming, Prince, & Parker |
The range of disparities encoded in primate V1 |
| 272 |
DeAngelis & Uka |
MT neurons can account for behavioral performance in a depth discrimination task |
| 273 |
Qiu, Endo, & von der Heydt |
Neural representation of 3-dimensional shape primitives in monkey visual cortex |
| 274 |
Kraft, Peirce, Forte, Krauskopf, & Lennie |
Nonlinear combination of binocular signals in macaque cortex |
| 275 |
Janssen, Vogels, Liu, & Orban |
The representation of vertical and horizontal disparity gradients in macaque inferior temporal cortex |
| 276 |
Mamassian & Sinha |
Apparent motion from apparent lightness |
| 277 |
Singh, De Kadt, & Anderson |
Predicting perceived transparency in textured displays |
| 278 |
Anderson |
What is the relationship between binocular disparity, contrast, and perceived depth? |
| 279 |
Beall & Herbert |
A Stroop analog task: Words versus facial expressions |
| 280 |
Pourtois, Rouw, & de Gelder |
The time course of face recognition : evidence for a dual route model |
| 281 |
Buelthoff & Newell |
Gender, average heads and categorical perception |
| 282 |
Nagayama, Miyatani, & Toshima |
The effects of temporal and spatial factor on face and non-face object recognition process: A study using the element presentation paradigm and working memory paradigm |
| 283 |
Simion, Scheier, Shimojo, & Shimojo |
Do we like what we see more or do we see more what we like? |
| 284 |
Osada & Nagasaka |
The effects of limited eye movements on judgments of emotion of band pass filtered faces |
| 285 |
Hill & Johnston |
Judging sex and identity from isolated facial movement |
| 286 |
Sato & Shigemasu |
Contribution of familiarity to reversed disparity illusion with human faces |
| 287 |
Ando |
Luminance-induced shift in the apparent direction of gaze |
| 288 |
Pusch & Loomis |
Judging another person's facing direction using peripheral vision |
| 289 |
Martelli, Majaj, Palomares, Leigh, Ekman, & Pelli |
Which features depend on which faces? |
| 290 |
Buschmann & Troje |
An illumination induced visual illusion that affects the perceived width of a human head |
| 291 |
Paul, Schyns, & Gosselin |
Category knowledge can form prior constraints on scene recognition from luminance and chromatic cues |
| 292 |
James, Humphrey, Vilis, Corrie, & Goodale |
Active and passive object recognition in a virtual environment |
| 293 |
Fulton & Moore |
The selection of environmental frames of reference |
| 294 |
Peters, Gabbiani, & Koch |
Models of object categorization reflect multiple categorization strategies |
| 295 |
Sadr & Sinha |
Random image structure evolution (RISE) |
| 296 |
Dawson |
Affective priming with masked, complex scenes |
| 297 |
Cutzu |
Computation of object features from object geometry and perceptual data |
| 298 |
Thoresz & Sinha |
Qualitative representations for recognition |
| 299 |
Torralba, Sinha, & Oliva |
Modeling contextual influences on object recognition |
| 300 |
Phillips & Voshell |
Contributions of geometric and image information in the perception of solid objects |
| 301 |
Jacobs, Lu, & Liu |
Image abstraction in shape representation and recognition |
| 302 |
Walker & Malik |
Defining perceptual metrics in shape space |
| 303 |
Macuga, Gray, & Regan |
Judging the direction of object motion-in-depth during simulated self-motion |
| 304 |
Brooks & Owens |
Effects of luminance, blur, and tunnel vision on postural stability |
| 305 |
Wilkie & Wann |
The contribution of flow, extra-retinal signals & visual frame to the control of steering |
| 306 |
Saidpour & Andersen |
Effects of speed and object motion in collision detection |
| 307 |
Pelah & Thurrell |
Reduction of perceived visual speed during locomotion: Evidence for quadrupedal perceptual pathways in human? |
| 308 |
Royden |
Computing heading in the presence of moving objects |
| 309 |
Malo, Gutierrez, & Epifanio |
What motion information is perceptually relevant? |
| 310 |
Gilmore, Stine, Smith, Venkatesh, Kehn, & Klass |
Infants' discrimination of heading direction from optic flow |
| 311 |
Peh, Panerai, Droulez, Cornilleau-Pérès, & Cheong |
Absolute distance perception during sagittal head motion |
| 312 |
DeLucia, Kaiser, Garcia, & Sweet |
Effects of relative size and height in field on absolute judgments of time to contact |
| 313 |
Ando |
Visual learning in the spatial prediction of an approaching 3D object |
| 314 |
Panerai, Droulez, & Cornilleau-Pérès |
Perception of object distances during self-motion: gauging the role of optical and oculomotor cues |
| 315 |
Zhong, Cornilleau-Peres, Cheong, Yeow, & Droulez |
Tilt perception from optic flow in two-view stimuli |
| 316 |
Dyre, Morrow, & Richman |
Heading performance is retinally invariant when peripheral optical flow is displayed off the axis of judgment |
| 317 |
Zikovitz, Jenkin, & Harris |
Comparison of stereoscopic and non-stereoscopic optic flow displays |
| 318 |
Berndt, Wascher, Franz, Goetz, & Büelthoff |
The effect of mirrored visual feedback on the EEG correlates of pointing direction |
| 319 |
Danckert, Sharif, & Goodale |
Intercepting moving targets in the upper and lower visual fields |
| 320 |
Schlicht, Schrater, Kersten, & Legge |
How well you reach depends on where you look |
| 321 |
Riecke, von der Heyde, & Bülthoff |
How real is virtual reality really? Comparing spatial updating using pointing tasks in real and virtual environments |
| 322 |
Bingham |
Distortions of distance and shape do not reflect a single continuous transformation on reach space |
| 323 |
Caudek & Domini |
Spatial and temporal surface interpolation in structure from motion |
| 324 |
Cornilleau-Peres, Tai, & Cheong |
Apparent distortion of the frontoparallel plane from wide-field motion parallax |
| 325 |
Yang & Purves |
Perception of objects that are both rotating and translating |
| 326 |
Braunstein, Bocheva, Zhong, & Sauer |
Judging depth, slant, and curvature in structure-from-motion |
| 327 |
Vuong, Domini, & Caudek |
Temporal integration in structure from motion |
| 328 |
Chen, Domini, & Caudek |
Perception of tilt: The role of the optic flow gradients |
| 329 |
Domini, Skirko, & Caudek |
Temporal integration of stereo and motion information |
| 330 |
Feria, Braunstein, Sauer, & Andersen |
Velocity difference and velocity ratio in structure-from-motion |
| 331 |
Mangini & Biederman |
Differentiating expression, gender, and identity in faces: Comparing normals, the ideal observer, and a prosopagnosic |
| 332 |
O'Toole, Leopold, Vetter, & Blanz |
Prototype-referenced shape perception : Adaptation and after-effects in a multidimensional face space |
| 333 |
Gosselin & Schyns |
Bubbles: A new technique to reveal the use of information in recognition tasks |
| 334 |
Tanaka & Porterfield |
The search for self-identity: The own-face effect |
| 335 |
Martini, McKone, & Nakayama |
Orientation tuning of human face processing estimated by contrast matching in transparency displays |
| 336 |
Liu, Lalonde, & Chaudhuri |
Are faces easier to recognize in 3/4 view than in full-face or profile view? |
| 337 |
Tarr, Kersten, Cheng, & Rossion |
It's Pat! Sexing faces using only red and green |
| 338 |
Knappmeyer, Thornton, & Buelthoff |
Facial motion can determine facial identity |
| 339 |
Schyns, Bonnar, & Gosselin |
The spatial scale information that mediates face identification, gender and expression |
| 340 |
Liu, Harris, & Kanwisher |
What makes a face a face: an MEG and fMRI study |
| 341 |
Downing & Kanwisher |
A cortical area specialized for visual processing of the human body |
| 342 |
Zenger-Landolt & Koch |
Attention reduces flanker suppression |
| 343 |
He, Costello, Carlson, Zhuang, Chen, & Hu |
What exactly does attention modulate in visual cortex? |
| 344 |
Saenz, Buracas, & Boynton |
Feature-based attentional effects in early human visual cortex |
| 345 |
Supèr, Spekreijse, & Lamme |
Contextual modulation in primary visual cortex as a neuronal substrate for working memory |
| 346 |
Scholte, Spekreijse, & Lamme |
Neural correlates of global scene segmentation are present during inattentional blindness |
| 347 |
Alvarez, Wolfe, Horowitz, & Arsenio |
Limits on multielement tracking |
| 348 |
Jovicich, Peters, Koch, Braun, Chang, & Ernst |
Brain areas specific for attentional load in a motion tracking task |
| 349 |
Wolfe |
Guided Search 4.0: A guided search model that does not require memory for rejected distractors |
| 350 |
Hochstein & Ahissar |
The ups and downs of conscious visual perception |
| 351 |
Pollick, Lestou, Ryu, & Cho |
Estimating efficiency in the categorization of biological motion |
| 352 |
Fujimoto, Yagi, & Sato |
Incompatible body-translation delays visual perception of human gait |
| 353 |
Paterson & Pollick |
Form and animacy in the perception of affect from biological motion |
| 354 |
Thornton, Cunningham, Troje, & Bülthoff |
"You can tell by the way I use my walk...": New studies of gender and gait |
| 355 |
Troje |
Decomposing biological motion: A linear model for analysis and synthesis of human gait patterns |
| 356 |
Giese |
Hierarchical neural model for the recognition of biological motion |
| 357 |
Jokisch, Midford, & Troje |
Biological motion as a cue for the perception of absolute size |
