| Attention: Selection over Time |
1 |
Shapiro, Martin, Arend, Johnston, & Klein |
The contingent negative variation (CNV) event-related potential (ERP) predicts the attentional blink |
| 2 |
MacLean, Stokes, Gicante, & Arnell |
The "working" component of working memory predicts AB magnitude |
| 3 |
Dale, Young, & Arnell |
That's my name, don't wear it out: Attentional blink and the cocktail party effect |
| 4 |
Kawahara |
When do additional distractors reduce and increase the attentional blink? |
| 5 |
Jefferies & Di Lollo |
Shrinking and shifting: Two alternative task-dependent modes of attentional control |
| 6 |
Hanus, Vul, & Kanwisher |
Delay of selective attention during the attentional blink |
| 7 |
Dux & Marois |
Individual differences in distractor priming during the attentional blink: Distractor inhibition gives rise to awareness |
| 8 |
Harris, Benito, & Dux |
Object processing in the absence of attention |
| 9 |
Chua |
Noise Overlay on the RSVP stream reduces the AB |
| 10 |
Sy & Giesbrecht |
Inter-trial switches in perceptual load modulate semantic processing during the attentional blink |
| 11 |
Elliott & Giesbrecht |
Rapid reconfiguration reduces the attentional blink |
| 12 |
Reiss, Hoffman, Heyward, Doran, & Most |
ERP Evidence for temporary loss of control during the attentional blink |
| 13 |
Oriet & Corbett |
Evidence for rapid extraction of average size in RSVP displays of circles |
| 14 |
Bridge, Choo, & Chiao |
Can race enhance perceptual awareness? Evidence from the attentional blink paradigm |
| 15 |
Trick, Brandigampola, & Enns |
Does the prolonged attentional blink to emotional stimuli affect driving performance? |
| Motion: Integration, Flow, and Depth |
16 |
Harvey, Cowey, & Braddick |
Similar processing for detection and position discrimination of expanding, contracting and rotating motion flow patterns in random dot kinematograms, shown by adaptation and TMS |
| 17 |
Wattam-Bell, Birtles, Li, Lin, Braddick, & Atkinson |
Coherence dependence of high-density visual evoked potentials to global form and motion displays |
| 18 |
Allard & Faubert |
Common first- and second-order motion processing at high temporal frequencies |
| 19 |
Liu & Sperling |
The perceived motion direction of fast-moving Type-II plaids |
| 20 |
Rider, Johnston, & McOwan |
Motion integration fields are dynamically elongated in the direction of motion |
| 21 |
Aaen-Stockdale & Hess |
Spatial scale invariance of the amblyopic global motion deficit |
| 22 |
Gillespie, Braunstein, & Andersen |
The perception of path curvature: Effects of projected velocity and projected size |
| 23 |
Takemura & Murakami |
Motion detection sensitivity enhanced by induced motion |
| 24 |
Clarke & Rainville |
Motion grouping/segmentation via velocity gradients |
| 25 |
Gomi & Nishida |
Visual motion interaction between central and peripheral visual fields for the manual following response |
| 26 |
Gilmore, Mattes, & Christensen |
Stability of SSVEP responses to optic flow |
| 27 |
Lew & Dyre |
Linear sub-space modeling responses to transparent motions comprised of radial dot flows |
| 28 |
Rokers, Cormack, & Huk |
Neural circuits underlying the perception of 3D motion |
| 29 |
Lee & Grzywacz |
Failure of decomposition of translation and expansion/rotation in optic-flow perception |
| 30 |
Alvarez, Hoffman, & Banks |
When are trajectories for motion-in-depth stimuli perceived accurately? |
| 31 |
Lee, Yuille, & Lu |
Superior perception of circular/radial than translational motion cannot be explained by generic priors |
| 32 |
Billino, Braun, Bremmer, & Gegenfurtner |
Effects of focal brain lesions on perception of different motion types |
| Object Perception: Neural Mechanisms |
33 |
Swisher, Brady, & Tong |
Visual denoising of object images along the ventral pathway |
| 34 |
Kim, Lescroart, Hayworth, & Biederman |
The release from adaptation in LOC from viewing a sequence of two different objects: An effect of shape or semantics? |
| 35 |
Hayworth, Lescroart, & Biederman |
Explicit relation coding in the Lateral Occipital Complex |
| 36 |
O'Brien, Rutherford, & Raymond |
Can value learning modulate low-level visual object recognition? An ERP study |
| 37 |
Chen & Haynes |
Invariant decoding of object categories from V1 and LOC across different colors, sizes and speeds |
| 38 |
Williams, Baker, Op de Beeck, Dang, Triantafyllou, & Kanwisher |
Location-invariant object information in foveal retinotopic cortex |
| 39 |
Vuong & Schultz |
Dynamic objects are more than the sum of their views: Behavioural and neural signatures of depth rotation in object recognition |
| 40 |
Drucker & Aguirre |
Integral versus separable perceptual dimensional pairs are reflected in conjoint versus independent neural populations |
| 41 |
Wu & Zhang |
Dissociate binding processing and object representation – a study combining EEG and fMRI |
| 42 |
Freeman, Donner, & Heeger |
Inter-area correlations in the human ventral visual pathway reflect feature integration |
| 43 |
Tan, Serre, Kreiman, & Poggio |
Implicit coding of location, scale and configural information in feedforward hierarchical models of the visual cortex |
| 44 |
Op de Beeck, Brants, Baeck, & Wagemans |
Does perceived shape underlie the category selectivity in human occipitotemporal cortex for faces, body parts, and buildings? |
| 45 |
Remus, Davidenko, Hu, Glover, & Grill-Spector |
Reliability of object- and face-selective activations measured with high-resolution fMRI |
| 46 |
Bao, Yue, & Tjan |
BOLD signal response functions for object and face processing in noise |
| Perception and Action: Hand Movements |
47 |
Byrne, Pallan, Yan, & Crawford |
Integration of object-centered and viewer-centered visual information in an open-loop pointing task |
| 48 |
Hu & Knill |
Visual feedback control of pointing movements in depth |
| 49 |
Lau, Roy, & Desmarais |
Effects of experience and amount of visual feedback when pointing to visible and remembered targets |
| 50 |
Rossit, Muir, Reeves, Duncan, Livingstone, Jackson, Castle, & Harvey |
Non-lateralized impairments in anti- but not pro-pointing in patients with hemispatial neglect |
| 51 |
Striemer, Blangero, Rossetti, Pisella, & Danckert |
Attention for action? Examining the link between attention and visuomotor control deficits in a patient with optic ataxia |
| 52 |
Brown, Culham, Kroliczak, & Goodale |
Improved blindsight near the hand is associated with increased fMRI activation in the superior parietal-occipital cortex |
| 53 |
Giese, Fleischer, & Casile |
Neural model for the visual recognition of hand actions |
| 54 |
Kwon & Shelton |
Intermittent feedback model of goal directed forearm movement |
| 55 |
Tremblay & Luis |
The use of visual information during a visual saccade for the control of a goal-directed upper limb movement |
| 56 |
Collins, Röder, & Schicke |
Movement intention versus motor preparation in the orientation of visuo-spatial attention: The case of tool use |
| 57 |
Killingsworth & Levin |
Motion interference effects while performing and viewing actions with hand-held objects |
| 58 |
Binsted, Brownell, & Heath |
It's all a matter of mass: Both the eye and hand know it |
| 59 |
Siegel, Budge, Gill, & Henriques |
Why does intermanual transfer occur? |
| 60 |
Buckingham, Binsted, & Carey |
Bimanual coupling in left and right space: which hand is yoked to which? |
| 61 |
Richters, Gabree, & Eskew |
Hand-eye correlation: Sensorimotor learning of movement/color pairs |
| 62 |
Blavier & Nyssen |
The impact of expertise on the processing of 2D and 3D images: The case of minimal invasive surgery |
| Central Pathways |
63 |
Amano, Wandell, & Dumoulin |
The visual field maps in the human MT+ complex |
| 64 |
Kuriki, Ashida, Murakami, & Kitaoka |
Functional brain imaging of the 'Rotating Snakes' illusion |
| 65 |
Smith & Wall |
Human brain regions that are responsive to optic flow only when the flow is consistent with egomotion |
| 66 |
Shim, Jiang, & Kanwisher |
Types and tokens in the ventral visual pathway: The neural representation of multiple visual objects |
| 67 |
Tamietto, Cauda, Latini Corazzini, Savazzi, Marzi, Goebel, Weiskrantz, & de Gelder |
Collicular vision guides non-conscious behavior |
| 68 |
Sireteanu, Oertel, Mohr, Haenschel, Linden, Maurer, Singer, & Schwarz |
Graphical illustration and functional neuroimaging of visual hallucinations during prolonged blindfolding: A comparison to visual imagery |
| Perceptual Organization 1 |
69 |
Ing & Geisler |
Patch pair statistics for leaf segmentation |
| 70 |
Ostrovsky, Leonova, & Sinha |
Binding the pieces: Efficacies of grouping cues |
| 71 |
Oliva & Brady |
Perceptual organization across spatial scales in natural images: Seeing more high spatial frequency than meet the eyes |
| 72 |
May & Hess |
Testing filter-overlap models of contour integration |
| 73 |
Mueller, Do, & Leopold |
Independent measures of adaptation and aftereffect |
| 74 |
Maloney & Mamassian |
The visual system uses different estimators for different distributions in a novel task even without feedback or the possibility of learning |
| 3D Perception and Image Statistics |
75 |
Backus |
The subjective reliability of a newly recruited visual cue is similar whether or not a long-trusted cue is also present in the stimulus |
| 76 |
Fleming, Li, & Adelson |
Image statistics for 3D shape estimation |
| 77 |
Girshick, Burge, Erlikhman, & Banks |
Prior expectations in slant perception: Has the visual system internalized natural scene geometry? |
| 78 |
Knill |
Learning shape-specific Bayesian priors for depth perception |
| 79 |
Todd, Christensen, & Guckes |
Nonlinear biases in the perception of 3D slant from texture |
| 80 |
Burge, Held, & Banks |
Blur and accommodation are metric depth cues |
| 81 |
Berryhill, Aguirre, & Olson |
Superior occipital regions track perceived viewing distance in two dimensional images |
| Object: Neural Mechanisms |
82 |
Sayres & Grill-Spector |
Retinal position and object category effects in human lateral occipital cortex |
| 83 |
Lescroart, Hayworth, & Biederman |
How translation invariant are object representations in the human posterior fusiform gyrus? |
| 84 |
Carlson, Hogendoorn, Fonteijn, & Verstraten |
Orthogonal representations of object category and location in object selective cortex |
| 85 |
Rajimehr, Devaney, Young, Postelnicu, & Tootell |
The 'Parahippocampal Place Area' responds selectively to high spatial frequencies in humans and monkeys |
| 86 |
Gorlin, Sharma, Sugihara, Sur, & Sinha |
Imaging prior information in the visual system |
| 87 |
Wong & Gauthier |
Neural correlates of music reading expertise |
| 88 |
Kriegeskorte, Simmons, Bellgowan, & Baker |
Circular inference in neuroscience: The dangers of double dipping |
| Binocular Mechanisms 1 |
89 |
Mamassian |
Depth, but not surface orientation, from binocular disparities |
| 90 |
Fantoni & Gerbino |
The orientation disparity field accounts for a slant by tilt anisotropy |
| 91 |
Farell & Julian |
Orientation difference, spatial separation, intervening stimuli: What degrades stereoacuity and what doesn't |
| 92 |
Stroyan |
Computation of the geometric inputs to depth perception |
| 93 |
Harris, Chopin, & Zeiner |
Individual differences in depth perception: are biases correlated with eye position? |
| 94 |
Ni & Andersen |
Propagation of depth from temporal inter-ocular unmatched features and binocular information |
| 95 |
Ishii, Yamashita, & Tang |
Binocular disparity as a cue to perceive direction |
| 96 |
Chen, Lu, Tanigawa, & Roe |
Stereo matching problem is resolved at population level in the early stage of extrastriate visual cortex |
| 97 |
Jurcoane, Mitsieva, Choubey, Muckli, & Sireteanu |
Interocular transfer of fMRI adaptation in stereodeficient observers |
| 98 |
Shigemasu, Miyawaki, Kamitani, & Kitazaki |
Decoding depth order and three-dimensional shape perception from human cortical activity of dorsal and ventral areas |
| 99 |
Giaschi, MacKenzie, Boden, Solski, & Wilcox |
The development of coarse stereopsis in school aged children |
| Eye Movements, Search and Attention |
100 |
Atapattu & Durgin |
Saccadic inhibition during information accrual in a visual search task |
| 101 |
Khan, Takahashi, Heinen, & McPeek |
The spatial extent of attention for saccades: Attentional facilitation compared to inhibition of return in humans and monkeys |
| 102 |
Adolph, Franchak, Badaly, Smith, & Babcock |
Head-mounted eye-tracking with children: Visual guidance of motor action |
| 103 |
Fazl & Mingolla |
Predicting eye movement trajectories in a multiple object tracking (MOT) task with free viewing |
| 104 |
Hafed & Krauzlis |
How inactivation of the superior colliculus can cause a constant eye position offset during object tracking |
| 105 |
Smith, Tsai, Wong, Brooks, & Peterson |
More than meets the eye: Investigating expert and novice differences in action video games |
| 106 |
Najemnik & Geisler |
Optimal continuous-time control of eye movements during visual search |
| 107 |
Myers & Gray |
Scan pattern adaptations to repeated visual search |
| 108 |
Mennie & Underwood |
Memory for objects and locations in visual search |
| 109 |
Montagnini & Castet |
Presaccadic deployment of attention: what is the trigger? |
| 110 |
Raj, Bovik, & Cormack |
Low-level fixation search in natural scenes by optimal extraction of texture-contrast information |
| 111 |
McKinney, Chajka, & Hayhoe |
Pro-active gaze control in squash |
| 112 |
Wyatte & Busey |
Low and high level changes in eye gaze behavior as a result of expertise |
| 113 |
Jovancevic, Sullivan, & Hayhoe |
Avoiding collisions in real and virtual environments |
| 114 |
Masciocchi, Mihalas, Parkhurst, & Niebur |
Interesting locations in natural scenes draw eye movements |
| 115 |
Logan, Zbrodoff, & Li |
Do the eyes count? The role of eye movements in visual enumeration |
| 116 |
Mayer & Vuong |
Biological motion in natural scenes captures eye movements |
| 117 |
Holm, Eriksson, & Andersson |
Looking as if you know: Eye guidance preceding object recognition |
| 118 |
Dodd, Van Der Stigchel, Hollingworth, & Kingstone |
Examining scanpaths and inhibition of return as a function of task instruction during scene viewing |
| 119 |
Born & Kerzel |
Stimulus contrast and the remote distractor effect: differential effects for foveal and peripheral distractors |
| 120 |
Van der Stigchel |
Oculomotor competition when working memory is occupied |
| Motion: Higher Mechanisms and Illusions |
121 |
Takeuchi & De Valois |
Feature-tracking mechanism dominates motion perception as the retinal illuminance decreases |
| 122 |
Giora & Gori |
Visual competition between ambiguous and unambiguous motion signals in grating patterns |
| 123 |
Kawachi, Grove, Sakurai, & Gyoba |
Two streams make a bounce: Induced motion reversal by crossing the trajectories of two motion sequences |
| 124 |
Inokuma & Sato |
Induced motion with chromatic stimuli |
| 125 |
Seno & Sato |
Vection induction is determined by the world coordinate |
| 126 |
Rushton, Sumner, & Singh |
The role of hMST in the perception of object movement during self-movement |
| 127 |
Maffei, Macaluso, Orban, & Lacquaniti |
The internal model of visual gravity contributes to interception of real and apparent motion as revealed by fMRI |
| 128 |
Pizlo, Kim, Talavage, Pizlo, & Steinman |
Neural substrate of the perception of phi (pure) movement |
| 129 |
Hayashi & Kawano |
Paradoxical motion perception observed through contrast-alternating multiple-slit-viewing |
| 130 |
Paymer, Caplovitz, & Tse |
Stimulus factors that influence the perceived direction of tilt-induced motion |
| 131 |
Yazdanbakhsh & Gori |
Why does rotating tilted lines Illusion rotate? |
| 132 |
Gori, Galmonte, & Agostini |
Can depth information affect the Enigma Illusion? |
| 133 |
Zenz & Cai |
The effect of metacontrast masking on the Fröhlich effect |
| Attention: Selection and Modulation 1 |
134 |
Prinzmetal & Ha |
A taxonomy of visual attention |
| 135 |
Guzman, Palafox, Grabowecky, & Suzuki |
A visual redundant-signal effect strongly depends on attention even for probability summation |
| 136 |
Puri, Whitney, & Ranganath |
Facilitatory effects of expectation on object discrimination |
| 137 |
Al-Aidroos, Ho, & Pratt |
Attentional control settings affect attention but not perception: A study of gaze cues and pupilometry |
| 138 |
Yigit, Palmer, & Moore |
Partially valid cueing and spatial filtering reveal different kinds of selection |
| 139 |
Park, Fuller, & Carrasco |
Cue salience modulates the effects of exogenous attention on apparent contrast |
| 140 |
Matthews |
Bilateral superiority in detecting gabor targets among gabor distracters |
| 141 |
Ghorashi, Jefferies, & Di Lollo |
Expansion and contraction of the attentional focus is influenced by top-down factors |
| 142 |
Fuller & Carrasco |
Perceptual consequences of visual performance fields: The case of the line motion illusion |
| 143 |
Flevaris, Bentin, & Robertson |
Attention to hierarchical level influences spatial frequency processing |
| 144 |
Abrams, Liu, & Carrasco |
Endogenous, sustained attention alters contrast appearance |
| 145 |
Shin & Chong |
Spatial attention to an invisible adaptor can increase the magnitude of adaptation |
| 146 |
Shimozaki |
The behavioural temporal dynamics of attention with multiple uncued locations |
| 147 |
Roggeveen, Jefferies, Sekuler, Bennett, & DiLollo |
The creaky attentional gate: Temporal changes in the spatial extent of attention in elderly and young observers |
| Faces: Inversion and Viewpoint Effects |
148 |
Tien, Lee, Tsai, & Hsu |
The inversion effect of Chinese character |
| 149 |
Nagai, Kazai, Bennett, Katayose, Yagi, Rutherford, & Sekuler |
The influence of eye and mouth position on judgments of face orientation |
| 150 |
Susilo, McKone, & Edwards |
Face adaptation aftereffects reveal norm-based coding for upright and inverted face shape |
| 151 |
Goffaux |
Face discrimination at various phase orientations |
| 152 |
Shannon, Jiang, & He |
Upright face advantage in visual information processing under interocular suppression only available for the low spatial frequency pathway |
| 153 |
Willenbockel, Fiset, Chauvin, Blais, Arguin, Tanaka, Bub, & Gosselin |
The face inversion effect is nothing "spatial" |
| 154 |
Pallett & MacLeod |
Face shape discrimination is insensitive to inversion |
| 155 |
Lee, Weiss, Haist, & Stiles |
Inversion disrupts both configural and featural face processing equally |
| 156 |
Busigny, Joubert, Felician, & Rossion |
Processing upright and inverted faces in acquired prosopagnosic patients with no object recognition deficits |
| 157 |
Rossion & Boremanse |
Nonlinear relationship between holistic processing of individual faces and picture-plane rotation: Evidence from the face composite illusion |
| 158 |
Wilson, Daar, Mohsenzadeh, & Wilkinson |
Independent discrimination of left/right and up/down head orientations |
| 159 |
Natu, Jiang, Narvekar, Keshvari, & O'Toole |
Representations of facial identity over changes in viewpoint |
| 160 |
Nishimura, Joglekar, & Maurer |
The effect of training on the recognition of faces across changes in viewpoint |
| 161 |
Weidenbacher & Neumann |
The first spike counts: A model for STDP learning pose specific representations for estimating view direction |
| 162 |
Davies-Thompson, Spyrou, & Andrews |
View-dependent adaptation to familiar and unfamiliar faces in the human brain |
| 163 |
McKone & Yovel |
A single holistic representation of spacing and feature shape in faces |
| 164 |
Chen & Tseng |
The role of external head contours in face processing in the human occipitotemporal cortex |
| 165 |
Rhodes, Michie, Hughes, & Byatt |
The Fusiform Face Area spontaneously codes spatial relations in faces |
| Multisensory Processing: Low Level |
166 |
Teng & Whitney |
Position discrimination of auditory stimuli in early visual cortex |
| 167 |
Tanaka, Nogai, & Munetsuna |
The locus of auditory-visual integration in the human brain |
| 168 |
Arnott, Cant, Dutton, Munhall, & Goodale |
Auditory-visual interactions in a patient with bilateral occipital lobe lesions |
| 169 |
Leung, Kim, Grabowecky, Paller, & Suzuki |
Cross-modal selective attention effects on steady-state visual evoked potentials (SSVEPs) |
| 170 |
Leone & McCourt |
Audiovisual multisensory facilitation: A fresh look at neural coactivation and inverse effectiveness |
| 171 |
Wozny, Seitz, & Shams |
Learning associations between simple visual and auditory features |
| 172 |
Matsumiya & Shioiri |
Haptic movements enhance visual motion aftereffect |
| 173 |
Gori, Sandini, & Burr |
Visual, tactile and visuo-tactile motion discrimination |
| 174 |
Vroomen & Keetels |
A sound can change four-dot masking |
| 175 |
Yeh, Chiu, & Hsiao |
The Gestaltist's error revisited with sound |
| 176 |
Yokosawa & Era |
Visual cue influence on three-dimensional haptic angle discrimination |
| Faces: Learning and Expertise |
177 |
Schneider, Harman-James, Wyatte, & Busey |
A noise x inversion paradigm reveals the nature of fingerprint expertise for latent print examiners in EEG and fMRI |
| 178 |
Busey, Schneider, & Wyatte |
Expertise and the width of the visual filter in fingerprint examiners |
| 179 |
Harel & Bentin |
Are all types of expertise created equal? Effects of expertise on categorization and spatial frequency usage |
| 180 |
Williams & Gauthier |
Can expertise explain why face perception is sensitive to spatial frequency content? |
| 181 |
de Heering & Rossion |
Prolonged visual experience in adulthood modulates perceptual face processes |
| 182 |
Luedeman & Nakayama |
Transferring localized facial learning across all of face space |
| 183 |
Chatterjee, Luedeman, & Nakayama |
A test to explore the learning of multiple novel faces |
| 184 |
DeGutis, Robertson, Nakayama, McGlinchey, & Milberg |
Learning faces: Plasticity and the rehabilitation of congenital prosopagnosia |
| 185 |
Hanif, Khalil, Malcolm, & Barton |
Predicting perceptual expertise from semantic knowledge: An indexed car test for prosopagnosic patients |
| Faces: Lifespan Development |
186 |
Nakato, Otsuka, Yamaguchi, & Kakigi |
Perception of mother's face using near-infrared spectroscopy |
| 187 |
Jeffery & Rhodes |
Aftereffects reveal enhanced face-coding plasticity in young children |
| 188 |
Kelly & Steeves |
The effects of losing an eye early in life on face and emotional expression processing |
| 189 |
Mondloch, Robbins, & Maurer |
A feature story: Similarities among adults, 10-year-olds and cataract-reversal patients in face discrimination |
| 190 |
Anzures, Ge, Zhe, Kelly, Pascalis, Quinn, Slater, & Lee |
Face feature processing in children: What develops and what does not? |
| 191 |
Von Der Heide, Wenger, Gilmore, Howarth, Sullivan, & Bittner |
Age-related differences in processing capacity for faces |
| 192 |
Crookes & McKone |
Childhood improvements in face performance result from general cognitive development not changes in face perception: Evidence from faces versus objects, inversion and implicit memory |
| 193 |
Karen & Vanitha |
Face inversion effects in infants are driven more by high, than low, spatial frequencies |
| 194 |
Shroff, Kim, Hefets, & Gerhardstein |
Children's sensitivity to configural cues in faces undergoing rotational motion |
| 195 |
Farzin, Rivera, & Whitney |
Holistic face processing in infants using mooney faces |
| 196 |
Murray, Ruffman, & Halberstadt |
Age-related changes in face processing |
| Visual Working Memory 1 |
197 |
Halko, Lymberis, & Somers |
Interactions between visual short term memory and visuospatial attention |
| 198 |
Huth, Wilimzig, Zinn, & Koch |
The indirect role of saliency in selection for short-term visual memory |
| 199 |
Brady, Konkle, Alvarez, & Oliva |
Compression in visual short-term memory: Using statistical regularities to form more efficient memory representations |
| 200 |
Johnson & Spencer |
Metric-dependent repulsion between colors in visual working memory |
| 201 |
Williams & Woodman |
Directed forgetting versus directed remembering in visual working memory |
| 202 |
Yamaguchi, Tuerk, & Feigenson |
Heterogeneous object arrays increase working memory capacity in 7-month old infants |
| 203 |
Sanocki & Sulman |
Visual short term memory for location: Does objecthood matter? |
| 204 |
Richard & Hollingworth |
Strategic control of visual short-term memory during scene viewing |
| 205 |
Tsubomi, Kondo, & Watanabe |
Common capacity limit for visual perception and working memory |
| 206 |
Lin & Sperling |
No iconic memory decay nor visual short-term memory decay for grating contrast |
| 207 |
Most, Wang, Engelhardt, & Curby |
Selective effects of emotion on visual short-term memory consolidation |
| 208 |
Ko & Seiffert |
Updating objects in visual short-term memory |
| 209 |
Umemoto, Scolari, Vogel, & Awh |
Implicit knowledge biases encoding into visual working memory |
| 210 |
Zhang & Luck |
Sudden death for overtime memories |
| 211 |
Rasmussen & Hollingworth |
The capacity for spatial updating in visual short-term memory |
| 212 |
Sligte, Scholte, & Lamme |
Activation in V4 predicts fragile or durable storage in visual working memory |
| 213 |
Fiser, Orban, & Lengyel |
Linking implicit chunk learning and the capacity of working memory |
| Eye Movements and Perception |
214 |
Martinez-Conde, Troncoso, & Macknik |
Microsaccades counteract perceptual filling-in |
| 215 |
Phillips, Steenrod, & Goldberg |
Saccade adaptation in monkeys is object-specific |
| 216 |
Leek & Johnston |
Fixation locations during three-dimensional object recognition are predicted by image segmentation points at concave surface intersections |
| 217 |
Richard, Churan, Guitton, & Pack |
Perceptual compression during head-free gaze shifts: visual and extraretinal contributions |
| 218 |
Schütz, Braun, Kerzel, & Gegenfurtner |
Improved visual sensitivity during smooth pursuit eye movements |
| 219 |
Sharan, Rosenholtz, & Adelson |
Eye movements for shape and material perception |
| Multiple Object Tracking 1 |
220 |
Howe, Livingstone, Morocz, Horowitz, & Wolfe |
A Neurophysiological model of multiple object tracking derived from fMRI |
| 221 |
Scalf & Beck |
Attentional capacity is limited by the functional architecture of visual cortex: competition for representation impedes attention to multiple items |
| 222 |
McCollough, Drew, Horowitz, & Vogel |
Probing the allocation of attention during multiple object tracking with ERPs |
| 223 |
Flombaum & Scholl |
How does attention operate during multiple object tracking?: Evidence from the 'slot-machine' task for parallel access to target features |
| 224 |
Awh, Scolari, & Ishikawa |
Object-based biased competition during covert spatial orienting |
| 225 |
Jiang, Vázquez, & Makovski |
Visual learning in multiple object tracking |
| Cortical Processing |
226 |
Chavane, Reynaud, & Masson |
The role of cortico-cortical interactions during motion integration: a voltage-sensitive dye imaging study in V1 and V2 of the awake monkey |
| 227 |
Tanigawa, Lu, Chen, & Roe |
Functional subdivisions in macaque V4 revealed by optical imaging in the behaving Macaque monkey |
| 228 |
Schmid, Mechler, Ohiorhenuan, Purpura, & Victor |
Processing of orientation discontinuities in space and time in V1 and V2 |
| 229 |
Kumbhani, El-Shamayleh, & Movshon |
Spatial and temporal limits of pattern motion analysis by mt neurons |
| 230 |
Hussar, Lui, & Pasternak |
Representation of stimulus speed in prefrontal cortex during speed discrimination task |
| 231 |
Cassanello, Nihalani, & Ferrera |
The role of the frontal eye fields in velocity compensation during saccades to moving targets |
| 232 |
Vangeneugden, Pollick, & Vogels |
Functional differentiation of macaque visual temporal cortical neurons using a parameterized action space |
| Attention: Divided Attention |
233 |
Horowitz, Wolfe, Cohen, Czeisler, & Klerman |
Quantifying the effects of sleepiness on sustained visual attention |
| 234 |
Halberda, Hunter, Pietroski, & Lidz |
An interface between language and vision: Quantifier words and set-based processing |
| 235 |
Lleras, Ahn, Levinthal, & Beck |
Neural correlates of inhibition to individual members of complex visual categories that have been recently rejected as distracting |
| 236 |
van Gaal, Ridderinkhof, Fahrenfort, & Lamme |
Unconsciously triggered inhibitory control is associated with frontal brain potentials |
| 237 |
Carter, Luedeman, Mitroff, & Nakayama |
Motion induced blindness: The more you attend the less you see |
| 238 |
Motoyoshi & Hayakawa |
Adaptation-induced blindness |
| 239 |
Kelley & Lavie |
Attentional learning: The role of distractor expectancy |
| Binocular Rivalry and Integration 1 |
240 |
Kang & Shevell |
The stabilization of a binocular percept during intermittent presentation |
| 241 |
Maehara, Huang, & Hess |
The importance of static phase-aligned, high spatial frequency components for continuous flash suppression |
| 242 |
Su, Ooi, & He |
Incompatible local features are unnecessary for binocular suppression |
| 243 |
Reavis, Afraz, & Nakayama |
Faces are privileged stimuli: The effect of stimulus characteristics on continuous flash suppression |
| 244 |
Zhang & He |
Voluntary attention can modulate eye-specific neural signals prior to the site of interocular competition |
| 245 |
St.Clair, Hong, & Shevell |
Misbinding of color to form in afterimages follows from a persisting binocular neural representation |
| 246 |
Ling & Blake |
Suppression during binocular rivalry broadens orientation tuning |
| 247 |
Alais, Apthorp, & Wenderoth |
Binocular rivalry between fast 'streaky' motions deeply suppresses static orientation probes: Evidence for motion streaks |
| 248 |
Breitmeyer, Pham, & Sheth |
How emotional arousal and affect influence access to visual awareness |
| 249 |
Kimura, Abe, & Goryo |
Pupillary response to grating patterns during permanent suppression |
| 250 |
Abe, Kimura, & Goryo |
Integration of color and pattern investigated with visibility modulation of chromatic gratings |
| 251 |
Lerner, Fukui, & Rubin |
Bi-stable perception and neural competition at equi-dominance and away from it |
| 252 |
Jackson, Brady, & Cummins |
Rotating walker: An ambiguous biological stimulus reveals biases in human vision |
| 253 |
Lamirel, Hupé, & Lorenceau |
Pupil dynamics during bistable form/motion binding |
| 254 |
Knapen, Pearson, Brascamp, van Ee, & Blake |
The role of frontal areas in alternations during perceptual bistability |
| 255 |
Chien, Chen, & Chen |
Can noises defeat will power in Necker cube reversals? Equating top-down influence with bottom-up bias with a noise paradigm |
| Faces: Other-race Effects |
256 |
O'Toole, Phillips, Narvekar, Jiang, & Ayyad |
Face recognition algorithms and the "other-race" effect |
| 257 |
Zhang, Ge, Wang, Kelly, Quinn, Slater, Pascalis, & Lee |
Two faces of the other-race effect: Recognition and categorization of Caucasians and Chinese Faces |
| 258 |
Fiset, Blais, Gosselin, Bub, & Tanaka |
Potent features for the categorization of Caucasian, African American, and Asian faces in Caucasian observers |
| 259 |
Lebrecht, Pierce, Tanaka, & Tarr |
Seeing beyond faces: The social significance of being an other-race expert |
| 260 |
Elms, Mondloch, Maurer, Hayward, Rhodes, Tanaka, & Zhou |
Other-race faces: Limitations of expert face processing |
| 261 |
Jaquet, Rhodes, & Hayward |
It's more than just physical: The contribution of social category information to race-selective face aftereffects |
| 262 |
Buttle & East |
Traditional facial tattoos disrupt face recognition processes |
| Spatial Vision: Mechanisms 1 |
263 |
Zlotnik, Ben Yaish, Yehezkel, Belkin, & Zalevsky |
Thin films as spectacles and contact lenses for aberration-corrected vision via brain adaptation to contrast |
| 264 |
Kubilius, Dilks, Baker, & Kanwisher |
The visual phantom illusion originates in "higher" cortical areas, not V1 |
| 265 |
Wolfson, Graham, & Pan |
Two contrast-adaptation processes: One old, one new |
| 266 |
Foley & Abbey |
Contrast discrimination in noise and classification images |
| 267 |
Kies & Chubb |
Perturbation analysis of perceptual templates |
| 268 |
Hairol & Waugh |
Cross-talk between luminance-defined and contrast-defined detection processing revealed by asymmetric lateral spatial interactions |
| 269 |
Waugh & Hairol |
Detecting overlapping luminance-defined and contrast-defined stimuli: Cue combination for better detection? |
| 270 |
Tomassini, Solomon, & Morgan |
When noisy means cardinal: visual biases for cardinal orientations revealed by degrading stimulus identity |
| 271 |
Mineault & Pack |
Getting the most out of classification images |
| 272 |
Huang & Hess |
Dynamics of collinear facilitation: Fast yet sustained |
| 273 |
Jeon, Lu, & Dosher |
Characterizing joint feature and contrast sensitivity of human observers |
| 274 |
Katkov & Sagi |
Lateral facilitation is largely due to internal response enhancement |
| 275 |
Kramer & Olzak |
The absence of a collinearity effect in second-order, contrast-modulation discrimination tasks |
| 276 |
Kim, Haun, & Essock |
The effect of sustained/transient temporal modulation on the horizontal effect of contrast masking |
| 277 |
Lev & Polat |
Filling-in in the periphery indicates that the collinear facilitation is similar to the fovea |
| 278 |
Levine, McAnany, & Anderson |
The effect of curvature on the grid illusions: Influence of a homunculus? |
| 279 |
Olzak & Hibbeler |
Second-order mechanisms do not process contrast-modulated orientation information optimally |
| 280 |
Poletti & Rucci |
Fixational eye movements and retinal activity during a single visual fixation |
| 281 |
Rosenberg, Husson, Mallik, & Issa |
Frequency-doubling in the early visual system underlies sensitivity to second-order stimuli |
| 282 |
Rubin, Chubb, Wright, Wong, & Sperling |
Spatiotemporal dynamics of the perception of dot displays |
| Lightness, Brightness and Luminance |
283 |
Allred, Lohnas, & Brainard |
Bayesian model of the staircase Gelb effect |
| 284 |
Anderson, de Silva, & Whitbread |
Lightness perception has no anchor |
| 285 |
Blakeslee, Reetz, & McCourt |
Spatial filtering versus anchoring accounts of brightness in staircase and simultaneous brightness contrast stimuli |
| 286 |
Radonjić, Escobar, Ivory, & Gilchrist |
The role of articulation and proximity in the effect of depth on lightness |
| 287 |
Rudd |
Ilumination frameworks, selective attention, and edge integration in lightness perception |
| 288 |
Shapiro, Knight, & Lu |
Spatial scale models of lightness illusions: contrast, anchoring, and tunable filters |
| 289 |
Gerhard & Maloney |
Albedo perturbation detection under illumination transformations: A dynamic analogue of lightness constancy |
| 290 |
Poirier, Gosselin, & Arguin |
Seeing through white clouds: When local occlusion cues fail |
| 291 |
McCourt & Blakeslee |
Coming to terms with lightness and brightness: effects of stimulus configuration and instructions on brightness and lightness judgments |
| 292 |
Vladusich |
Brightness, darkness and the perception of surface material |
| 293 |
Robinson & de Sa |
Measuring brightness induction during brief stimulus displays |
| 294 |
Horiguchi, Nakadomari, Furuta, Masuda, Asakawa, Koike, Kan, Misaki, Miyauchi, & Wandell |
The balance between transient and sustained temporal response varies across the V1 visual field map |
| 295 |
Heitz, Woodman, Pouget, Cohen, & Schall |
Effects of luminance contrast on visual responses in frontal eye field |
| Perception and Action: Reaching and Grasping |
296 |
Christopoulos & Schrater |
Identifying strategies for grasping objects with position uncertainty using empirical cost-to-go functions |
| 297 |
Watt, Keefe, & Hibbard |
Visual uncertainty predicts grasping when monocular cues are removed but not when binocular cues are removed |
| 298 |
Franz & Bruno |
Visually guided grasping and the Müller-Lyer illusion: As for pointing, the data look contradictory but in fact they are not |
| 299 |
Desanghere & Marotta |
Gaze strategies while grasping: What are you looking at?! |
| 300 |
Hesse & Franz |
Adaptive grasping: Corrective processes after perturbations of object size |
| 301 |
Mon-Williams & Bingham |
Calibration of grasp orientation (and 'wiggle-room' for errors in object orientation perception) |
| 302 |
Keefe, Elsby, & Watt |
Visually guided grasping: Using a small stimulus set can lead to overestimation of the effectiveness of depth cues |
| 303 |
Gonzalez, Brown, & Goodale |
No visual field advantage for visually-guided grasping movements made with the left hand |
| 304 |
Charles, Kent, Jansson, & Mon-Williams |
Visible surface area and prehension movement patterns |
| 305 |
Harvey, Muir, Reeves, Duncan, Livingstone, Jackson, Castle, & Rossit |
Pointing and bisection in open and closed loop reaching in patients with hemispatial neglect |
| 306 |
Issen & Knill |
The weight to spatial memory in visually-guided reaching increases with retinal eccentricity |
| 307 |
Bulakowski, Post, & Whitney |
Differential spatial integration for perception and action revealed by perceptual and visuomotor crowding |
| 308 |
Neva, Siegel, & Henriques |
Equivalent visuomotor adaptation for variable reach practice |
| 309 |
Anderson & Bingham |
Visually guided reaching using proportional rate control of disparity tau: Data and model |
| Search 1 |
310 |
Pedersini, Van Wert, Horowitz, & Wolfe |
Monetary reward does not cure the prevalence effect in a baggage-screening task |
| 311 |
Kunar, Flusberg, & Wolfe |
Why don't people use memory when repeatedly searching though an over-learned visual display? |
| 312 |
Van Wert, Nova, Horowitz, & Wolfe |
What does performance on one visual search task tell you about performance on another? |
| 313 |
Fleck & Mitroff |
Videogamers excel at finding rare targets |
| 314 |
Gao, Newman, & Scholl |
The psychophysics of chasing |
| 315 |
Williams, Pollatsek, Cave, & Stroud |
More than just finding color: Strategy in global visual search is shaped by learned target probabilities |
| 316 |
Yang, Oh, Leung, & Zelinsky |
An effect of WM load on visual search guidance: Evidence from eye movements and functional brain imaging |
| 317 |
Schmidt & Zelinsky |
Visual search guidance increases with a delay between target cue and search |
| 318 |
Lanagan-Leitzel & Moore |
Novice and expert performance on a computerized lifeguarding task |
| 319 |
Godwin, Menneer, Cave, Helman, Way, & Donnelly |
Don't distract the searcher: search performance for X-ray security screening images is reduced with the addition of a simple mental arithmetic task |
| 320 |
Droll & Eckstein |
Expected object position of two hundred fifty observers predicts first fixations of seventy seven separate observers during search |
| 321 |
Gaid, Mills, & Wilcox |
The role of meaning in visual search |
| 322 |
Hillstrom, Menneer, Donnelly, & Krokos |
Using gaze measures to diagnose what guides search in complex displays |
| 323 |
Liesker, Brenner, & Smeets |
Target overshoot when searching for a stationary target by moving a window or by moving a scene behind a stationary window |
| 324 |
Palmer, Brown, Clausner, & Kellman |
Visual search in air traffic control: Altitude correlated depth cues enhance conflict detection |
| 325 |
Rigutti, Gerbino, & Fantoni |
Layout following and visual search for web labels |
| 326 |
Shive & Francis |
Applying models of visual search to map design |
| 327 |
Yoshida, Kashiwada, Kajiwara, Kitahara, & Wake |
Two categories of glaucoma patients tell us the contribution of peripheral vision on visual search |
| Scene Perception 1 |
328 |
Moore & Stephens |
When two are one and one is two: Apparent motion, visible persistence, and scene organization |
| 329 |
Amit, Trope, & Yovel |
A distance principle of organization of the ventral visual stream |
| 330 |
Caddigan, Walther, Fei-Fei, & Beck |
Decoding of natural scene categories from transformed images using distributed patterns of fMRI activity |
| 331 |
Gaspar & Rousselet |
Probability summation and phase spectrum are sufficient to support animal detection in multiple scenes |
| 332 |
Steeves, Mullin, & Démonet |
Preserved house discrimination in a patient with acquired object agnosia |
| 333 |
Ward, Parker, Feiler, & Epstein |
Adaptation for individual places but not for place categories in scene-selective cortical regions |
| 334 |
Sanders, Haberman, & Whitney |
Mean representation beyond a shadow of a doubt: Summary statistical representation of shadows and lighting direction |
| 335 |
Christensen & Todd |
The role of bias in human contour labeling |
| 336 |
Sulman & Sanocki |
The effects of valence and attentional focus on the remembered size of objects in affective scenes |
| 337 |
Gardner, Fowlkes, Nothelfer, & Palmer |
Exploring aesthetic principles of spatial composition through stock photography |
| Spatial Vision: Natural Images and Texture |
338 |
DelPozo, Savarese, Baker, & Simons |
Why do we see some surfaces as reflective? |
| 339 |
Nishida, Motoyoshi, Nakano, Li, Sharan, & Adelson |
Do colored highlights look like highlights? |
| 340 |
Yoonessi & Kingdom |
Is color patchy? |
| 341 |
Del Viva & Punzi |
Finding meaningful patterns in visual images |
| 342 |
Iwaki, Haberman, Post, & Whitney |
The frozen face effect: Why static photographs don't do you justice |
| 343 |
Harp, Haberman, & Whitney |
Temporal integration of high-level summary statistical representation |
| 344 |
Knoblauch & Maloney |
Classification images estimated by generalized additive models |
| 345 |
Olman, Boyaci, Fang, & Doerschner |
V1 responses to different types of luminance histogram contrast |
| 346 |
Ellemberg, Johnson, & Hansen |
The development of natural image contrast sensitivity |
| 347 |
Hansen & Hess |
Local orientation and texture fixation statistics during free-viewing of natural scene images following brief adaptation |
| 348 |
Rucci, Desbordes, & Casile |
Fixational eye movements and retinal activity across multiple visual fixations |
| 349 |
Haun & Essock |
Contrast sensitivity in 1/f noise considered across spatial frequency band |
| 350 |
Baker, Yoonessi, & Arsenault |
Texture segmentation in natural images: Contribution of higher-order image statistics to psychophysical performance |
| 351 |
Prins |
Knowing which channel is relevant does not improve performance in texture segmentation |
| 352 |
Scofield, Chubb, & Sperling |
Analyzing band-selective preattentive texture mechanisms |
| 353 |
Webb, Ledgeway, & McGraw |
Adaptive spatial integration of orientation signals over time |
| 354 |
Fermuller, Xu, & Ji |
A view-point invariant texture descriptor |
| Temporal Processing and Dynamics |
355 |
Battelli, Van Rullen, & Pascual-Leone |
The continuous Wagon Wheel Illusion and the 'When' pathway of the right parietal lobe: An rTMS study |
| 356 |
Brenner & Smeets |
Mislocalising flashes in time |
| 357 |
Rüter, Scharnowski, Kammer, & Herzog |
How TMS and stimulus off/on signals modulate feature integration |
| 358 |
D'Antona, Kremers, & Shevell |
A cortical and a sub-cortical origin of lateral interactions in perceived temporal variation |
| 359 |
Cooper & Ramsden |
Color modulation of temporal response to oriented stimulation in macaque V2 |
| 360 |
Pechenkova |
Effects of context on visual temporal order judgments in RSVP |
| 361 |
Takei, Fujisaki, & Nishida |
Perceptual latency of sound-induced visual bounce |
| 362 |
Poggel, Calmanti, Treutwein, & Strasburger |
The Toelz temporal topography study: Mapping the visual field of temporal processing across the life span |
| 363 |
Rainville & Clarke |
The dynamics of shape coding for glass patterns |
| 364 |
Bruno, Ayhan, & Johnston |
Retinotopic adaptation can influence the apparent duration of a visual stimulus |
| 365 |
Maertens & Shapley |
Apparent duration is influenced by the geometrical (perceptual) meaningfulness of the stimulus |
| 366 |
Mulligan & Stevenson |
A frequency sweep method for rapid estimation of visual delays |
| 367 |
Holcombe & Linares |
Poor temporal precision in judging the position of a moving object, imposed at a late stage of visual processing |
| 368 |
Dill & Krauzlis |
Reaction times and perceptual judgments are atypical in autism |
| 369 |
Blais, Arguin, & Gosselin |
Visual processing oscillation fossils |
| 370 |
Benav, Wilke, Stett, & Zrenner |
A model for temporal features of visual sensations evoked by a subretinal electrode array for restoration of vision |
| Perception and Action: How Dissociated Are They? |
371 |
Goodale, Wolf, Whitwell, Brown, Cant, Chapman, Witt, Arnott, Khan, Chouinard, Culham, & Dutton |
Preserved motion processing and visuomotor control in a patient with large bilateral lesions of occipitotemporal cortex |
| 372 |
Culham, Witt, Valyear, Dutton, & Goodale |
Preserved processing of motion and dorsal stream functions in a patient with large bilateral lesions of occipitotemporal cortex |
| 373 |
Fattori, Breveglieri, Marzocchi, Bosco, & Galletti |
A medial parieto-occipital area coding all phases of prehension movements |
| 374 |
Ferrera, Yanike, & Cassanello |
The role of monkey frontal eye field in visual categorization |
| 375 |
Makin, Holmes, Brozzoli, Rossetti, & Farnè |
Hand-centered visual representation of space: TMS evidence for early modulation of motor cortex excitability |
| 376 |
Thaler & Todd |
Evidence from visuo-motor adaptation for two partially independent visuo-motor systems |
| Search 2 |
377 |
Hickey & Theeuwes |
ERP correlates of inter-trial effects in visual search |
| 378 |
Jungé |
Configuration asymmetries in visual search |
| 379 |
Schoonveld & Eckstein |
A likelihood based metric to compare human and model eye movement fixations during visual search |
| 380 |
Zelinsky, Zhang, & Samaras |
Eye can read your mind: Decoding eye movements to reveal the targets of categorical search tasks |
| 381 |
Foulsham, Barton, Kingstone, Dewhurst, & Underwood |
Eye movements and saliency in a natural search task: evidence from visual agnosia |
| 382 |
Kuzmova, Wolfe, Rich, Brown, Lindsey, & Reijnen |
PINK: the most colorful mystery in visual search |
| Motion Processing |
383 |
Drewes, Barthelemy, & Masson |
Human ocular following and natural scene statistics |
| 384 |
Masson, Fleuriet, Montagnini, & Mamassian |
Predicting and computing 2D target motion for smooth-pursuit eye movements in macaque monkeys |
| 385 |
Tse & Hsieh |
Smooth pursuit eye movements generate spurious motion signals that create a motion after effect |
| 386 |
Edwards, Vallam, & Kalia |
Tuning properties of local-motion pooling units |
| 387 |
Tadin & Glasser |
Rapid generation of the motion after-effect by sub-threshold adapting stimuli |
| 388 |
Lewis, Sekuler, & Bennett |
Psychophysical measurements of surround suppression in 5-year-olds |
| 389 |
Churan, Khawaja, Tsui, Richard, & Pack |
Effects of onset-transients on the perception of visual motion |
| Attention: Neural Mechanisms and Models |
390 |
Lovejoy & Krauzlis |
Inactivation of superior colliculus causes visual extinction |
| 391 |
Cohen, Heitz, Schall, & Woodman |
Timing of target selection between visual cortex and frontal eye field |
| 392 |
Noudoost & Moore |
Effects of frontal eye field inactivation on visual responses of area V4 neurons |
| 393 |
Fang, Boyaci, & Kersten |
Border ownership representation in human early visual cortex and its modulation by attention |
| 394 |
Mevorach, Humphreys, & Shalev |
Reflexive and preparatory selection and suppression of salient information in the right and left posterior parietal cortex |
| 395 |
Dosher, Lu, & Han |
Parallel architectures in visual search within an eye movement |
| 396 |
Sperling, Scofield, & Hsu |
Computational model of the spatial resolution of visual attention |
| Faces: Neural Mechanisms 1 |
397 |
Morash, Cherian, & Sinha |
The magnetoencephalography M170 response to degraded images |
| 398 |
Rousselet, Pernet, Bennett, & Sekuler |
Rapid extraction of stimulus phase information during complex object processing |
| 399 |
Stephanie, Olivier, Meike, Corentin, & Bruno |
Early electrophysiological correlates of the influence of familiarity during face identity adaptation paradigm |
| 400 |
Heisz & Shedden |
Holistic facial representation is required for some but not all face processing: Evidence from event-related potentials |
| 401 |
Yovel, Sadeh, Podlipsky, Hendler, & Zhdanov |
The face-selective ERP component (N170) is correlated with the face-selective areas in the fusiform gyrus (FFA) and the superior temporal sulcus (fSTS) but not the occipital face area (OFA): a simultaneous fMRI-EEG study |
| 402 |
Caldara, Mayer, & Caldara |
The occipital face area is not necessary for symmetry perception in faces |
| 403 |
Caldara, Jenkins, Brennan, Condon, Hadley, & Mayer |
Gaze direction is in the eye of the Superior Temporal Sulcus |
| 404 |
Axelrod & Yovel |
Invariant representation of face identity in the fusiform face area (FFA): The effect of external facial information |
| 405 |
Sekunova, Fox, Iaria, & Barton |
Encoding of age-invariant identity versus identity-invariant age from faces: An fMRI-adaptation study |
| 406 |
Iaria, Fox, & Barton |
Dynamic versus static stimuli for localization of the cerebral areas involved in face perception |
| 407 |
Meng, Singal, Cherian, & Sinha |
Neural correlates of categorical face perception |
| 408 |
Mur, Ruff, Bodurka, Bandettini, & Kriegeskorte |
Ranking 96 object images by their activation of FFA |
| 409 |
Jiang, Dricot, Blanz, Goebel, & Rossion |
Representation of 3D face shape and 2D surface reflectance in the ventral temporal cortex |
| 410 |
Dricot, Busigny, & Rossion |
Behavioral and neural evidence for preserved holistic face detection in acquired prosopagnosia |
| 411 |
Duchaine & Garrido |
Reversed visual field advantage for face matching in developmental prosopagnosia |
| 412 |
Schmalzl, Palermo, Green, Brunsdon, & Coltheart |
Training of familiar face recognition and visual scan paths for faces in a child with congenital prosopagnosia |
| 413 |
Hoover, Démonet, & Steeves |
Cross-modal identity recognition in a patient with prosopagnosia |
| Perceptual Development Across the Lifespan |
414 |
Adams, MacNeil, Dove, & Courage |
Optics and psychophysics in a clinical setting: Success of a screening battery for assessing visual functioning in human infants |
| 415 |
Ciaramitaro & Dobkins |
Cross-modal influences on low-level sensory processing early in development |
| 416 |
Reis, Ranvaud, & Canto-Pereira |
Spatial distribution of visual attention during childhood |
| 417 |
Zosh & Feigenson |
Array heterogeneity prevents catastrophic working memory failure in infants |
| 418 |
Roudaia, Bennett, & Sekuler |
High-contrast contour integration and aging |
| 419 |
Dessalegn & Landau |
Vision and language: Recoding of visual representations |
| 420 |
Gregory, McCloskey, & Landau |
The representation of the orientation of objects in children |
| 421 |
Taylor, Jakobson, Maurer, & Lewis |
Form and motion processing in preterm children |
| 422 |
Janette, Dee, Shirley, Oliver, Mary, Frances, & David |
High-density VEP measures of global form and motion processing in infants born very preterm |
| 423 |
Candy, Baker, & Norcia |
Orientation tuning in the visual cortex of human infants |
| 424 |
Govenlock, Kliegl, Sekuler, & Bennett |
Assessing the effect of aging on orientation selectivity of visual mechanisms with the steady state visually evoked potential |
| 425 |
Klein & Brooks |
Impact of luminance and blur combinations on older drivers acuity and preferred speed |
| 426 |
Greffou & Faubert |
Life-span study of visually driven postural reactivity: A fully immersive virtual reality approach |
| 427 |
Piotrowski & Jakobson |
Age-related changes in the representational momentum effect |
| Spatial Vision: Crowding and Eccentricity 1 |
428 |
Fischer & Whitney |
A crowded face influences the ensemble representation of a set of faces |
| 429 |
Fortenbaugh & Robertson |
Visual boundaries and perceived eccentricity: Evidence that boundary reduction changes the scale of space |
| 430 |
Mareschal, Solomon, & Morgan |
The opposite of crowding revealed using classification images |
| 431 |
McGraw, Whitaker, & Levi |
Amblyopic eyes are particularly susceptible to motion-induced distortions of space |
| 432 |
Montaser-Kouhsari & Carrasco |
Perceived spatial frequency varies as a function of location in the visual field |
| 433 |
Nakano, Rosenholtz, & Balas |
A texture-perception model of crowding for general stimuli, Version 1.0 |
| 434 |
Rislove & Levi |
Crowding and feature conjunction in human amblyopia |
| 435 |
Saarela, Sayim, Westheimer, & Herzog |
Configural modulation of crowding |
| 436 |
Sayim, Westheimer, & Herzog |
Figural grouping affects contextual modulation in low level vision |
| 437 |
Song & Levi |
Spatio-temporal map of crowding in normal and amblyopic vision |
| 438 |
Sun, Chung, & Tjan |
Mechanisms of crowding and learning to "uncrowd" |
| 439 |
Tjan, Nandy, & Chung |
Crowding in the amblyopic fovea can be unlike crowding in the normal periphery |
| 440 |
Wu & Cavanagh |
Retinal mapping can distort to avoid the "impossible space" outside the visual field |
| 441 |
Zhang, Liu, & Yu |
Evidence for misplaced target information with letter crowding |
| 3D Pictorial Cues |
442 |
Held & Banks |
Perceived size is affected by blur and accommodation |
| 443 |
de Montalembert, Auclair, & Mamassian |
Where is the sun for hemi-neglect patients? |
| 444 |
O'Shea, Agrawala, & Banks |
The preferred angle of illumination in shape from shading |
| 445 |
Schofield & Sun |
Shape-from-shading for grating stimuli: Slant is proportional to luminance, with some exceptions |
| 446 |
Savarese, Del Pozo, Baker, & Simons |
When are reflections useful in perceiving the shape of shiny surfaces? |
| 447 |
Sun & Schofield |
High frequency textures provide better support for shape-from-shading than low frequency textures |
| 448 |
Fujii, Kaneko, & Mizushina |
Effect of texture continuity on depth threshold |
| 449 |
Li & Zaidi |
Unmasking of orientation flows in 3-D shape perception |
| 450 |
Wong & Zaidi |
Matched filters for 3-D shape from kernel-based image analysis |
| 451 |
Cheng & Yonas |
Perception of impossible line drawings by pre-school children |
| 452 |
Li & Pizlo |
Perception of 3D shapes from line drawings |
| 453 |
Sawada & Pizlo |
Detection of mirror-symmetry of a volumetric shape from its single 2D orthographic image |
| 454 |
Papathomas, Sherman, & Jain |
The role of perspective and angle polarity in perceiving 3D objects: Lessons from reverspectives |
| 455 |
Sakai, Fujita, Parron, & Fagot |
Ecological account for ground dominance: Comparisons between terrestrial and arboreal primates |
| 456 |
Bian & Andersen |
The ground surface advantage in change detection: coherent surface structure |
| 457 |
Shavit, Li, & Matin |
The influences of array orientation and of line orientation on visually perceived eye level (VPEL) are modulated by line length and array length |
| 458 |
Li & Matin |
Spatial induction, laterality, and homogeneity of perceived space |
| Attention: Inattentional Blindness and Change Detection |
459 |
Simons & Jensen |
The effects of individual differences and task difficulty on inattentional blindness |
| 460 |
Olson |
Inattentional blindness: Driver compliance rates at pedestrian crosswalks |
| 461 |
Angelone & Severino |
Effects of individual differences on the ability to detect changes in natural scenes |
| 462 |
Asano, Kanaya, & Yokosawa |
Proofreaders show a generalized ability to allocate attention to detect changes |
| 463 |
Brady & Allen |
Change blindness and fearsome objects |
| 464 |
Caplovitz, Fendrich, & Hughes |
Seeing changes without seeing what changed |
| 465 |
Hayes, Swallow, & Jiang |
Competitive interaction for visual representation between and within hemifields |
| 466 |
Ichikawa |
Change blindness for relatively moving target as a result of a single mudsplash |
| 467 |
Kabata & Matsumoto |
The probability of change influences attentional allocation in foreground- background segmentation |
| 468 |
Murakoshi & Osada |
The effects of active attention on the change detection task |
| Perceptual Learning 2 |
469 |
Trommershauser, Mamassian, & Maloney |
Preference in a stochastic visual cognitive task with probability information learned through experience |
| 470 |
Benson, Kersten, & Schrater |
Decision making in an uncertain video game environment |
| 471 |
West, Stevens, Pun, & Pratt |
Video game playing enhances practical attentional skills |
| 472 |
Li, Polat, & Bavelier |
Playing action video games enhance visual sensitivity |
| 473 |
Baluch & Itti |
Effects of training on perceptual salience |
| 474 |
MacKenzie & Fiser |
Sensitivity of implicit visual rule-learning to the saliency of the stimuli |
| 475 |
Pierce, Krigolson, Tanaka, & Holroyd |
Reinforcement learning and the acquisition of perceptual expertise in ERPs |
| 476 |
Dilks, Baker, Liu, & Kanwisher |
Rapid reorganization in the adult human visual system |
| 477 |
Kim, Seitz, & Watanabe |
Reward contingency on perceptual learning does not follow rules of classical conditioning |
| 478 |
Tsushima, Seitz, & Watanabe |
Task-irrelevant perceptual learning occurs only when the irrelevant feature is weak |
| 479 |
Tartaglia, Aaberg, & Herzog |
Roving in perceptual learning: stimulus interference and overlapping neural populations |
| 480 |
Ayhan, Bruno, & Johnston |
Adaptation induced temporal compression is highly space specific |
| 481 |
Sheehan, Bingham, & Mon-Williams |
Task space calibration in Cartesian coordinates |
| Higher Cortical Processing |
482 |
Garcia, Srinivasan, & Grossman |
TMS-induced oscillations in orientation discriminations |
| 483 |
Grosbras & Lauder |
Frontal eye field and visual motion discrimination: A transcranial magnetic stimulation study |
| 484 |
Balslev & Miall |
Degraded eye proprioception after 1Hz rTMS over the anterior parietal cortex |
| 485 |
Heinrich, Mell, & Bach |
Improving the signal-to-noise ratio of the visual P300 |
| 486 |
Fuggetta, Silvanto, Muggleton, Pavone, Feurra, Sartori, Marzi, & Walsh |
Electrophysiological evidence for the role of extrastriate visual cortex in visual awareness |
| 487 |
Macknik & Martinez-Conde |
The role of feedback in visual masking, visual awareness and attention |
| 488 |
Yoshida, Takaura, & Isa |
Neural correlate of visual awareness in the superior colliculus of the animal model of blindsight |
| 489 |
Mullin, Démonet, & Steeves |
No McCollough effect in a patient with cerebral achromatopsia but spared V1 |
| 490 |
Rosenau, Greenberg, Sunness, & Yantis |
Cortical lesion projection zone activity in retinal disease patients is caused by object-specific feedback, not plasticity |
| 491 |
Wolynski, Kanowski, & Hoffmann |
Response lateralisations in visuo-motor cortex and consequences of abnormal visual input |
| 492 |
Zohary, Dilks, Kanwisher, & Pascual-Leone |
Does cortical reorganization lead to a corresponding change in readout? |
| 493 |
Konen, Pinsk, Arcaro, & Kastner |
Object representations in the dorsal pathway: fMRI adaptation effects in macaque posterior parietal cortex |
| 494 |
Weiner & Grill-Spector |
Repetition suppression and category selectivity in the human ventral stream: fMRI evidence for the scaling model |
| 495 |
Wilson, Pearson, Jakobson, Bolster, Marotta, & Sboto-Frankenstein |
Colour and texture processing in human extrastriate cortex: An fMRI study |
| 496 |
He, Ma, Jiang, Gong, Liu, Cao, Deng, Chen, & Weng |
Identification and characterization of the Visual Character Form Area (VCFA) in Chinese readers and illiterates |
| Multiple Object Tracking 2 |
497 |
Haladjian & Pylyshyn |
Object-specific preview benefit enhanced during explicit Multiple Object Tracking |
| 498 |
Frank, Vul, Mansinghka, & Alvarez |
What limits performance in multiple object tracking? |
| 499 |
Drew, Horowitz, Wolfe, & Vogel |
Online measurement of dynamic changes in tracking load |
| 500 |
Mednick, Cai, Rieth, Kanady, & Horowitz |
Separating specific from general learning in a napping paradigm on Multiple Object Tracking and Rotary Pursuit tasks |
| 501 |
Rich, Van Wert, Cohen, & Horowitz |
Multiple object tracking is surprisingly robust to abrupt onsets |
| 502 |
Linares, White, & Holcombe |
Object localization at speeds below and above the attentive tracking limit |
| 503 |
Makovski & Jiang |
The interdependence between multiple attentional foci in attentive tracking |
| 504 |
Fehd & Seiffert |
Attention to the center of the target array during multiple object tracking |
| 505 |
Doran & Hoffman |
Spatial attention in multiple object tracking: Evidence from ERPs |
| 506 |
Huff, Jahn, & Schwan |
Abrupt viewpoint changes during multiple object tracking |
| 507 |
Mettler, Keane, & Kellman |
Contour interpolation affects multiple object tracking |
| 508 |
Spencer & Perone |
A dynamic neural field model of multi-object tracking |
| 509 |
Tinjust, Allard, & Faubert |
Impact of stereoscopic vision and 3D representation of visual space on multiple object tracking performance |
| 510 |
Tripathy, Kennedy, & Barrett |
Early adulthood losses in the effective number of tracked trajectories in human vision |
| Object Perception: Recognition and Categorization |
511 |
Nandakumar & Malik |
Rapid object category detection in visually degraded stimuli |
| 512 |
Kim & Chong |
Do you know what it is as soon as you know it is there? |
| 513 |
Mack & Palmeri |
Dissociating detection and categorization: As soon as you know it is there, you don't necessarily know what it is |
| 514 |
Hayward & Pasqualotto |
2D images are not sufficient for testing 3D object recognition |
| 515 |
Reppa & Leek |
Effects of viewing time and viewpoint changes on 3D shape recognition: Evidence for the role of nonvolumetric primitives in 3D shape representation |
| 516 |
Liu |
Learning sequence of views of three-dimensional objects: The effect of temporal coherence on object memory |
| 517 |
Niimi & Yokosawa |
Three-quarter view is good because object orientation is uncertain |
| 518 |
Kravitz, Vinson, & Baker |
Position independence in object recognition |
| 519 |
Galperin, Bex, & Fiser |
The relationship between local feature distributions and object recognition |
| 520 |
Cant & Goodale |
Interaction between outline shape and surface-property processing in object recognition |
| 521 |
Desmarais, Dixon, & Roy |
Task characteristics modulate the impact of action similarity on visual object identification |
| 522 |
Liao & Shimojo |
Novelty vs. familiarity principles in preference decision: Task-context of memory matters |
| Cross-Modal Interactions |
523 |
Held, Ostrovsky, deGelder, & Sinha |
Revisiting the molyneux question |
| 524 |
Saenz & Koch |
Hearing motion in "the mind's ear" - evidence for a vision-to-sound synesthesia |
| Cross-modal Interactions |
525 |
Jarick, Dixon, Maxwell, & Smilek |
Time-space associations in synaesthesia: When input modality matters |
| Cross-Modal Interactions |
526 |
Di Luca, Ernst, & Adams |
Amodal multimodal integration |
| 527 |
Bulkin, Werner-Reiss, & Groh |
Visual information in the ascending auditory pathway |
| 528 |
Maij, Brenner, & Smeets |
An irrelevant sound can change peri-saccadic mislocalisation |
| Faces: Neural Mechanisms 2 |
529 |
Herzmann, Kunina, Wilhelm, & Sommer |
Individual differences in face cognition: Distinct component abilities and basic neural processes |
| 530 |
Nestor & Tarr |
Task-specific feature codes for face processing |
| 531 |
Davidenko, Remus, Ramscar, & Grill-Spector |
Stronger face-selective responses to typical versus distinctive faces when stimulus variability is controlled |
| 532 |
Harris & Aguirre |
The effects of parts, wholes, and familiarity on face-selective responses in MEG |
| 533 |
Moulson, Balas, Nelson, & Sinha |
EEG correlates of categorical and graded face perception |
| 534 |
Tanaka & Pierce |
The neural and behavioral plasticity of other-race face recognition |
| Binocular Mechanisms 2 |
535 |
Filippini & Banks |
The reliability of disparity signals affects slant anisotropy |
| 536 |
Allison, Gillam, & Palmisano |
Binocular slant discrimination beyond interaction space |
| 537 |
Hoffman & Banks |
Using focus cues in solving the binocular correspondence problem |
| 538 |
Donner, Sagi, Bonneh, & Heeger |
Distinct neural signatures of motion-induced blindness in human visual cortex |
| 539 |
Likova & Tyler |
The human cortical network for coherent stereomotion processing |
| 540 |
Tyler |
The dynamics of binocular combination |
| 541 |
Welchman, Preston, & Li |
Functional specialisation for the perception of disparity-defined depth in the human visual cortex |
| Decision and Reward |
542 |
Rothkopf & Ballard |
Human eye movements correlate with intrinsic reward structure in natural visuomotor tasks |
| 543 |
Schlicht, Shimojo, & Nakayama |
Learning probability and reward through experience: Impact of value structure on reach planning |
| 544 |
Seydell, McCann, Trommershaeuser, & Knill |
Learning to behave optimally in a probabilistic environment |
| 545 |
Wu & Maloney |
Neural correlates of value and probability in decision under risk and in an equivalent visuo-motor task |
| 546 |
Campos, Koppitch, Andersen, & Shimojo |
Overlapping representation of juice and video rewards in primate OFC |
| 547 |
Song & McPeek |
Target selection for visually-guided reaching in the dorsal premotor area during a visual search task |
| 548 |
Navalpakkam, Koch, & Perona |
Homo economicus in visual search |
| Attention: Object-based Selection |
549 |
Moya, Shomstein, Bagic, & Behrmann |
The time course of neural activity in object-based visual attention |
| 550 |
Albrecht, List, & Robertson |
Differences in object-based attention in the foreground and background |
| 551 |
Ball & Raymond |
Object–oriented perception of emotional information |
| 552 |
Xu |
Neural fate of unattended features in object-based encoding |
| 553 |
Drummond & Shomstein |
Object-based attention: Attentional certainty vs. attentional shifting |
| 554 |
Ester, Awh, Vogel, & Serences |
Attention does not automatically spread to all features of an object |
| 555 |
Esterman & Yantis |
Category expectation modulates object-selective cortical activity |
| 556 |
Liu, Dosher, & Lu |
Object attention in extended objects has few effects on accuracy |
| 557 |
Neill, Burnham, O'Connor, & Li |
Effects of object structure on object-based attention |
| 558 |
Robertson, Albrecht, Fortenbaugh, & Antonenko |
The effect of awareness on hemispheric asymmetries in object-based processing |
| 559 |
Wede & Francis |
Attention increases the perceived strength of illusory contours |
| 560 |
Chen |
Feature binding through anticipatory inhibition |
| Color Perception |
561 |
Logvinenko & Lu |
Unique hue isochromes in the equiluminant plane |
| 562 |
Altschuler, Huang, Hon, Goris-Rosales, & Tyler |
Simultaneous color contrast, afterimages and metameric intransitivity: Novel effects and explanation of previously enigmatic results |
| 563 |
VanHorn & Francis |
Switch color afterimages depend on the luminance of the viewing surface |
| 564 |
Mizokami, Tanaka, & Yaguchi |
Color contrast effect under natural and unnatural viewing conditions |
| 565 |
Sun & Shevell |
What L/M cone-signal pooling is consistent with the Rayleigh matches of carriers of deuteranopia? |
| 566 |
Zdravkovic |
The influence of object identity on lightness constancy |
| 567 |
Bressanelli & Gori |
Impossible transparency becomes possible also without stratification indexes: A new example of illusory transparency due to motion |
| 568 |
Rutan, Pospisil, & Sacoto |
A Microphotogoniometer for the measurement of gloss and its correlation with visual perception |
| 569 |
te Pas & Pont |
Perception of the diffuseness of the light source and of the number of light sources in photographs of real objects is predicted by image statistics regardless of shape and material of the objects |
| 570 |
Christiansen, D'Antona, & Shevell |
Neural pathways of induced steady color shifts caused by temporally varying context |
| 571 |
Tokunaga, Logvinenko, & Maloney |
Colour dissimilarities under neutral light sources differing in intensity measured using two competing methods |
| 572 |
Amano & Foster |
Categorical color perception in natural scenes under different illuminants |
| 573 |
Hedrich, Ruppertsberg, & Bloj |
Colour constancy for real 3D and 2D scenes under typical and atypical illuminant changes |
| 574 |
Olkkonen, Hansen, & Gegenfurtner |
The structure of color space is largely invariant under illuminant changes |
| 575 |
Monnier |
Searching for variegated elements |
| 576 |
Yang, Kanazawa, & Yamaguchi |
Perception of neon color spreading in 3- to 6-month old infants |
| 577 |
Witzel, Hansen, & Gegenfurtner |
Categorical discrimination of colour |
| 578 |
Lindsey & Brown |
Diversity in English color name usage |
| 579 |
Nolan, Riley, & Loveall |
Color naming based on clinical visual condition: A surprising interaction |
| 580 |
Schloss, Lawler, & Palmer |
The color of music |
| 581 |
Cheng, Wu, & Wu |
An EOG-assisted saccade-contingent color breakup-free display |
| Perceptual Organization: Contours |
582 |
Hadad & Kimchi |
Grouping of shape by perceptual closure: Effects of spatial proximity and collinearity |
| 583 |
Hilger & Kellman |
Misalignment constraints on visual interpolation |
| 584 |
Keane, Lu, & Kellman |
Contour interpolation and lightness induction mechanisms interact to produce classification image features in a shape discrimination task |
| 585 |
Markovic |
Figural constraints on contour discontinuity detection |
| 586 |
Schinkel-Bielefeld, Ernst, Mandon, Neitzel, Kreiter, Pawelzik, & Rosenholtz |
Connection structures underlying human contour integration |
| 587 |
Spehar & Halim |
Spatial localization of interpolated contours |
| 588 |
Unuma, Hasegawa, & Kellman |
Contour and surface integration behind moving occluder |
| 589 |
Vergeer, Anstis, & van Lier |
Spatial averaging of afterimages between contours |
| 590 |
Sterkin, Sterkin, & Polat |
Spatio-temporal neuronal interactions as a basis for perceptual binding |
| 591 |
Feltner & Kiorpes |
Behavioral evidence for the perception of Kanizsa illusory contours in pig-tailed Macaque Monkeys (M. nemestrina) |
| 592 |
Stubbs & Stubbs |
Photographic exploration of illusory contours |
| 593 |
Sweeny, Grabowecky, Paller, & Suzuki |
Random and systematic effects of neural noise on low-level and high-level pattern vision |
| Motion: Space and Speed |
594 |
Doerschner, Kersten, & Schrater |
Analysis of shape-dependent specular motion - predicting shiny and matte appearance |
| 595 |
Cohen & Zaidi |
Motion perception driven by inferred shape properties |
| 596 |
Lagacé-Nadon, Allard, & Faubert |
Exploring the spatiotemporal properties of fractal rotation |
| 597 |
Maruya, Kanai, & Sato |
Motion of motion-defined pattern does not induce spatial mislocalization |
| 598 |
Hisakata & Murakami |
The transient temporal processing system contributes to motion perception in a static figure |
| 599 |
Hubbard, Kumar, & Carp |
Effects of spatial cue timing and relevance on representational momentum |
| 600 |
Cohen, Howe, Horowtiz, & Wolfe |
Support for a postdictive account of the flash-lag effect |
| 601 |
Hidaka, Nagai, & Gyoba |
Non-reversed motion perception induced by the spatiotemporal reversal of apparent motion sequences |
| 602 |
Hu & Victor |
Isodipole textures in spacetime: a novel non-Fourier and reverse-phi motion stimulus |
| 603 |
Nguyen-Tri & Faubert |
Possible mechanisms for pedestal effects on speed perception |
| 604 |
Murakami & Kaneko |
The perceived duration of motion increases with speed |
| 605 |
Vaziri Pashkam & Cavanagh |
Blur increases perceived speed |
| 606 |
Norman, Norman, Pattison, Craft, Wiesemann, & Taylor |
The role of explicit and implicit standards in speed discrimination |
| Perception and Action: Goal Directed Movements |
607 |
Liston & Stone |
Shared effects of prior information and reward on motor and perceptual choices |
| 608 |
Whitwell, Lambert, & Goodale |
Visuomotor planning cannot take advantage of conscious knowledge of future events |
| 609 |
Wilson, van Bergen, van Swieten, Kent, & Mon-Williams |
Perceptual and performance biases in action selection |
| 610 |
Modabber, Neva, Gill, Budge, & Henriques |
Learning and retaining visuomotor adaptation across time |
| 611 |
Bamford & Ward |
Predispositions to approach and avoid are contextually sensitive and goal dependent |
| 612 |
Chapman, Kirshen, & Goodale |
Seeing all the obstacles in your way: The effect of visual feedback on obstacle avoidance |
| 613 |
Heath, Neely, Yakimishyn, & Binsted |
Visuomotor performance and visuomotor memory operate without conscious awareness of intrinsic target features |
| 614 |
Wolfe, Gerhard, LaCasse, & Maloney |
Estimates of performance in a visuo-motor task are accurate, but not after joint movement is constrained |
| 615 |
Bingham & Anderson |
Perceptual information for the control of walking-to-reach |
| 616 |
Cinelli, Warren, & Hollands |
Do walkers follow their eyes? Further tests of the gaze-angle strategy for steering control |
| 617 |
Dabbagh, Desmarais, Roy, & Dixon |
Comparing the impact of incorrect object identification on object use to the impact of incorrect action production on naming objects |
| 618 |
Fulvio, Hudson, & Maloney |
Motor extrapolation of occluded spatiotemporal contours |
| 619 |
Ganel & Chajut |
Sensitivity of visuomotor control to real and to illusory size |
| 620 |
Linkenauger & Proffitt |
The effect of intention and bodily capabilities on the perception of size |
| 621 |
Fajen, Diaz, & Cramer |
Reconsidering the role of action in perceiving the catchability of fly balls |
| 622 |
Diaz, Phillips, & Fajen |
Intercepting moving targets: A little foresight helps a lot |
| 623 |
McBeath, Bahill, Nathan, & Baldwin |
Baseball's paradoxical pop up: Physics and fielder control strategy can lead to lurching |
| 624 |
Wolf, Whitwell, Brown, Cant, Chapman, Witt, Arnott, Khan, Chouinard, Culham, Dutton, & Goodale |
Preserved visual abilities following large bilateral lesions of the occipitotemporal cortex |
| Reading |
625 |
Barton, Fox, Sekunova, & Iaria |
What is the visual word form area encoding? An adaptation study contrasting handwriting with word identity |
| 626 |
Bilenko, Rajimehr, Young, & Tootell |
The visual cortical 'word form area' is selective for high spatial frequencies in humans but not monkeys |
| 627 |
Scharff & Ahumada |
Contrast polarity in letter identification |
| 628 |
Arguin, Poirier, & Gosselin |
Visual spread reading: Noisy letters in their natural context |
| 629 |
Yu, Gerold, Park, & Legge |
Reading horizontal and vertical english text |
| 630 |
Lu & Arditi |
User interface software for low vision access to the internet |
| Eye Movements |
631 |
Garaas & Pomplun |
The effect of attention size and information density on saccadic adaptation during real-world image search |
| 632 |
Goltz, Leung, Mirabella, Abuhaleeqa, Colpa, Blakeman, & Wong |
Effects of age, target characteristics, and viewing distance on ocular counterroll in healthy humans |
| 633 |
Wilmer & Backus |
Behavioral genetic evidence for plasticity in the oculomotor system |
| 634 |
Bradley & Geisler |
Eye movement strategies in a fixation search task: Humans versus models |
| 635 |
Wichmann, Kienzle, Schölkopf, & Franz |
Visual saliency re-visited: Center-surround patterns emerge as optimal predictors for human fixation targets |
| 636 |
Johnston & Leek |
Fixation Region Overlap Analysis (FROA) - A data driven approach to hypothesis testing using eye gaze fixation data |
| 637 |
Ostendorf, Schoder, Stricker, & Ploner |
Perisaccadic mislocalization in slow saccades |
| 638 |
Troncoso, Macknik, Otero-Millan, & Martinez-Conde |
Microsaccades drive illusory motion in "Enigma" |
| 639 |
Xu & Edelman |
Disruption of voluntary saccade commands by abruptly appearing visual stimuli |
| 640 |
Zhou, Johnson, Gurnsey, & von Grünau |
Eye movement strategies: A comparison between individuals with normal vision and simulated scotomas |
| 641 |
Renninger, Dang, Verghese, & Fletcher |
Effect of central scotoma on eye movement behavior |
| 642 |
Pospisil & Rutan |
Mean gaze duration validates self-reports of image importance |
| 643 |
Kelly, Jack, Blais, Caldara, Rossion, Scheepers, & Caldara |
Inverting faces does not abolish cultural diversity in eye movements |
| 644 |
Jasse, Vighetto, Vukusic, Pelisson, Pisella, & Tilikete |
Unusual mechanism of monocular oscillopsia |
| 645 |
Dewhurst & Crundall |
Training eye movements: Can training people where to look hinder the processing of fixated objects? |
| 646 |
Daniels, Howard, & Allison |
Gain of cyclovergence as a function of stimulus location |
| 647 |
Chang, Gordon, Shuttleworth, & Saldanha |
Translators' ocular measures and cognitive loads during translation |
| 648 |
Fitzhugh, Shipley, PhD, Newcombe, PhD, McKenna, & Dumay |
Mental rotation of real word Shepard-Metzler figures: An eye tracking study |
| Object Perception 1 |
649 |
Tao, Yan, Liu, & Sun |
Dissociation of egocentric and object-centric processing in mental rotation of hand: Effect of viewpoints of the visual stimulus and the viewers' own hands |
| 650 |
Stransky, Dubrowski, Carnahan, & Wilcox |
Mental rotation: Cross-task training and generalization |
| 651 |
Haji-Khamneh, Dyde, Sanderson, Jenkin, & Harris |
How long does it take for the visual environment to influence the perceptual upright? |
| 652 |
Veenemans, Carlson, Wu, & Verstraten |
Letter identity misplaced in space and time |
| 653 |
Cantone, Tillman, & Pelli |
Eccentric features integrate slowly |
| 654 |
He, Zhou, Zhang, Chen, & Zhuo |
Connectedness and inside/outside relation affect dot numerical judgment: implications for perceptual objects defined by topological attributes |
| 655 |
Choo & Franconeri |
Unseen objects can contribute to visual size averaging |
| 656 |
Manchin, Kravitz, & Baker |
Visual statistical learning: Spatial configuration or abstract association? |
| 657 |
Ehinger & Oliva |
Characterizing the shape and texture of natural objects using Active Appearance Models |
| Smooth Pursuit and Perception |
658 |
Braun, Schütz, & Gegenfurtner |
Object recognition during eye movements |
| 659 |
Rasche & Gegenfurtner |
The control of gaze in dynamic random noise displays |
| 660 |
Tchernikov & Fallah |
Selection of superimposed surfaces by speed |
| 661 |
Nawrot & Joyce |
Hering's law tested with the pursuit theory of motion parallax |
| 662 |
Buchholz & Fallah |
Selection of superimposed surfaces by density |
| 663 |
Terao, Watanabe, Yagi, & Nishida |
Improvement of chromatic temporal resolution during smooth pursuit eye movement |
| 664 |
Spering, Schuetz, & Gegenfurtner |
Smooth pursuit eye movements and the prediction of visual motion |
| 665 |
Souto, Montagnini, & Masson |
Scaling of anticipatory smooth pursuit eye movements with target speed probability |
| 666 |
Krauzlis & Nummela |
Superior colliculus inactivation biases target selection for smooth pursuit, saccades, and manual responses |
| 667 |
Jin, Watamanuik, Reeves, & Heinen |
Peripheral motion enhances target selection during smooth pursuit |
| 668 |
Freeman, Kolarik, & Margrain |
Accuracy and precision of tracking eye movements as a function of age |
| 669 |
O'Connor, Freeman, & Margrain |
Sensitivity to retinal and extra-retinal motion signals as a function of age |
| 670 |
Davies & Freeman |
Simultaneously adapting retinal motion and smooth pursuit eye movement in orthogonal directions |
| 671 |
Wismeijer, Knapen, van Ee, & Erkelens |
Influence of perspective and disparity on vergence smooth pursuit |
| 672 |
Badler, Lefèvre, & Missal |
Anticipatory pursuit is influenced by a concurrent duration reproduction task |
| 673 |
Ballard & Hayhoe |
Fixations gain reward by reducing model uncertainties |
| Global and Biological Motion |
674 |
Braddick, Wattam-Bell, Birtles, Loesch, Loesch, Frazier, & Atkinson |
Brain activity evoked by motion direction changes and by global motion coherence shows different spatial distributions |
| 675 |
Lu |
Biological motion is not identifiable by motion alone |
| 676 |
Jastorff & Orban |
fMRI reveals distinct processing of form and motion features in biological motion displays |
| 677 |
Koldewyn, Whitney, & Rivera |
Neural bases of visual motion perception deficits in autism |
| 678 |
Warren & Rushton |
Phantom flow parsing: Global visual compensation for observer movement-entrained retinal motion |
| 679 |
Liu, Adelson, & Freeman |
Human-assisted motion annotation for real-world videos |
| Attention to Objects and Scenes |
680 |
Li & Logan |
Object-based attention: Beyond gestalt principles |
| 681 |
Hwang & Pomplun |
A model of top-down control of attention during visual search in real-world scenes |
| 682 |
Mundhenk, Einhäuser, & Itti |
Natural Image RSVP task performance is predicted by measurements of bottom-up Bayesian Surprise exhibited by image sequences |
| 683 |
Wilimzig, VanRullen, & Koch |
A new masking technique for natural scenes reveals the saliency of an image |
| 684 |
New, Schultz, Wolf, Niehaus, Klin, & Scholl |
The scope of social attention deficits in autism: Prioritized orienting to people and animals in static natural scenes |
| 685 |
Elder, Balaban, Kamyab, Wilcox, & Hou |
Selectivity for faces as exogenous attentional cues |
| Spatial Vision: Natural Scene Statistics |
686 |
Scholte, Ghebreab, Smeulders, & Lamme |
The parvo and magno-cellular systems encode natural image statistics parameters |
| 687 |
Baddeley & Attewell |
The temporal properties of contrast adaptation are matched to the statistics of illumination change in the natural world |
| 688 |
Bex |
Sensitivity to spatial distortion in natural scenes |
| 689 |
Joo & Chong |
The attentional blink does not disrupt computation of the mean size |
| 690 |
Palomares, Pettet, Vildavski, Hou, & Norcia |
Visual evoked potentials for dynamic Glass pattern perception in 4-5 month old infants |
| 691 |
Burr & Ross |
A visual sense of number |
| 692 |
Morgan, Chubb, & Solomon |
The visual system removes sensory noise from the representation of a texture |
| Visual Memory |
693 |
Hochstein, Yakovlev, Romani, & Amit |
Memory mechanisms for familiarity recognition and identification |
| 694 |
Konkle, Brady, Alvarez, & Oliva |
Remembering thousands of objects with high fidelity |
| 695 |
Turk-Browne, Johnson, Chun, & Scholl |
Neural evidence of statistical learning: Incidental detection and anticipation of regularities |
| 696 |
Campana & Casco |
The neural basis of implicit short-term memory: TMS investigations of visual priming |
| 697 |
Woodman, Kang, St. Clair, & Schall |
Increases in gamma-band activity do not predict spatial working memory retention in macaque monkeys |
| 698 |
Najjar, Vul, & Alvarez |
Information limits visual short term memory |
| 699 |
Higgins, Simons, & Wang |
Popping in and out of existence: The effect of gradual and abrupt occlusion on object localization |
| Faces: Emotion |
700 |
Pitcher, Garrido, Walsh, & Duchaine |
TMS disrupts the perception and embodiment of facial expressions |
| 701 |
Suzuki, Goh, Sutton, Hebrank, Jenkins, Flicker, & Park |
Emotion suppresses repetition suppression of faces |
| 702 |
Gomez-Cuerva, Jackson, & Raymond |
Identification of expressive faces in the attentional blink |
| 703 |
Stienen & De Gelder |
Contrasting target visibility and visual awareness in unconscious emotional body perception |
| 704 |
Palermo, Atkinson, Willis, De Lissa, Sewell, & McArthur |
Implicit and explicit processing of facial expression in childhood, adolescence and adulthood: An ERP study |
| 705 |
Gao & Maurer |
Surprised but not scared: Similarities and differences in the perceptual structure of facial expressions of 7-year-olds and adults |
| 706 |
Jack, Blais, Caldara, Scheepers, & Caldara |
Lost in translation: Culturally tuned eye movements impair decoding of facial expression signals |
| 707 |
Roy, Roy, Hammal, Fiset, Blais, Jemel, & Gosselin |
The use of spatio-temporal Information in decoding facial expression of emotions |
| 708 |
Fox, Iaria, Duchaine, & Barton |
Behavioral and fMRI studies of identity and expression perception in acquired prosopagnosia |
| 709 |
Smith, Harris, & Steeves |
Strategy for visual scanning of faces varies with the degree of Asperger Syndrome traits |
| 710 |
Roy, Roy, Fiset, Hammal, Blais, Rainville, & Gosselin |
Recognizing static and dynamic facial expressions of pain : Gaze-tracking and Bubbles experiments |
| 711 |
Schirillo & Powell |
Fearing Rembrandt's male portraits (Hess Revisited) |
| 712 |
Juricevic & Webster |
Adaptation to facial expressions |
| 713 |
Martinez & Neth |
Emotion perception in neutral expressions |
| 714 |
Smith |
The effect of stimulus duration on the processing of facial expressions of emotion – an EEG study |
| 715 |
Grabowecky, Sweeny, Paller, & Suzuki |
When anger spreads to one's neighbors: Within-hemifield averaging of facial expressions |
| 716 |
Conway, Jones, DeBruine, & Little |
Evidence for adaptive design in human gaze preference |
| Perceptual Organization: 2D Shape |
717 |
Wilder, Feldman, & Singh |
Shape classification based on natural shape statistics |
| 718 |
Briscoe, Singh, & Feldman |
Shape skeletons and shape similarity |
| 719 |
Singh & Feldman |
Skeleton-based segmentation of shapes into parts |
| 720 |
Barenholtz |
Convexities move, concavities follow |
| 721 |
Kim & Feldman |
Globally inconsistent figure/ground relations induced by negative parts |
| 722 |
Bell & Badcock |
Detection of globally processed radial frequency contours: Narrow-band shape channels integrate luminance and contrast cues |
| 723 |
Betts, Rainville, & Wilson |
Adaptation to radial frequency patterns in the lateral occipital cortex |
| 724 |
Kurki & Saarinen |
Interplay between pattern density and global form in Glass patterns |
| 725 |
Bittner, Wenger, Von Der Heide, & Sullivan |
Common elements of perceptual organization: Illusory contours and dimensional consistency |
| 726 |
Miyamoto & Murakami |
Perceptual filling-in on a natural blind spot influences pupillary light reflex |
| 727 |
Naito & Kaite |
Does the luminance condition for test figures change the illusion? |
| 728 |
Friedenberg, Liby, & Flores |
Center of mass estimation in three-body displays. The influence of median length and orientation |
| 729 |
Aguirre & Drucker |
fMRI used to distinguish conjoint and independent representation of perceptual axes |
| 730 |
Palmer & Guidi |
Exploring shape using goodness-of-fit measures |
| 731 |
Mou, Li, & McNamara |
Intrinsic orientation and learning viewpoint in shape recognition |
| 732 |
Nagasaka, Brooks, & Wasserman |
Prior experience affects amodal completion in bonobos |
| 733 |
Carson & Allard |
Artists drawing angles: An expertise approach |
| Scene Perception 2 |
734 |
Siagian & Itti |
Comparison of gist models in rapid scene categorization tasks |
| 735 |
Huang & Grossberg |
Scene understanding using attentional control of gist and texture information |
| 736 |
Johnson & Zhang |
Spatiotemporal influence of colour on scene gist perception |
| 737 |
Larson, Loschky, Matz, Smerchek, Weber, & Berger |
The roles of central versus peripheral visual information in recognizing scene gist |
| 738 |
Loschky, Larson, Smerchek, & Finan |
The superordinate natural/man-made distinction is perceived before basic level distinctions in scene gist recognition |
| 739 |
Shelton, Lau, Zacks, & Yoon |
The opportunistic use of reference frames for rotating scene stimuli |
| 740 |
Michod, Dickinson, & Intraub |
Multiple fixations do not enhance spatial memory for scene layout |
| 741 |
Dickinson & Intraub |
Spatial biases in scanning and remembering scenes |
| 742 |
Chang, Rotello, Li, & Rayner |
Scene perception and memory revealed by eye movements and ROC analysis: Does a cultural difference truly exist? |
| 743 |
Ozkan & Braunstein |
The perceived trajectory of objects crossing the perceptual horizon in a 3-D scene |
| 744 |
Boloix |
A multinomial processing tree model of change blindness and change detection |
| 3D Space Perception |
745 |
Alvarez & Robertson |
Differences in feature vs object binding across depth: Evidence from grapheme-color synesthesia |
| 746 |
Corbett & Carrasco |
Visual performance fields are retinotopic |
| 747 |
Toskovic |
Importance of proprioceptive and vestibular information for visual space anisotropy |
| 748 |
Gajewski, Philbeck, Chichka, & Pothier |
Exploring the time course of egocentric distance perception with visual masking of a real-world environment |
| 749 |
Interrante, Ries, Kaeding, & Anderson |
Exploring the effects of self-representation on spatial perception in immersive virtual environments |
| 750 |
Kozhevnikov, Royan, & Gorbunov |
The role if immersion in three-dimensional spatial processing |
| 751 |
Kuhl, Thompson, & Creem-Regehr |
Angle of declination manipulations and their effects on distance judgments in virtual environments |
| 752 |
Zhao, Wang, Jiang, Wu, & Sun |
Estimation of distance on flat and uphill terrains using visual matching and blind walking task |
| 753 |
Woods & Philbeck |
Comparison of rope-pulling and blindwalking as measures of perceived egocentric distance |
| 754 |
Tarampi, Creem-Regehr, & Thompson |
Visually directed walking to targets viewed with severely degraded vision is surprisingly accurate |
| 755 |
Russell & Durgin |
Demand characteristics, not effort: The role of backpacks in judging distance |
| 756 |
Stefanucci & Geuss |
Changing spaces: Body size influences the perception of aperture width |
| 757 |
Siegel, Geuss, & Stefanucci |
Studying the relationship between emotion and height perception in naturalistic settings |
| 758 |
Egan, Phillips, & Norman |
What sculpted depictions of 3-D objects reveal about visual and haptic mental representations |
| 759 |
Lee, Lind, & Bingham |
Metric shape perception requires a 45° continuous perspective change |
| 760 |
Witt & Proffitt |
Playing air guitar eliminates effect of ability on perceived distance |
| Attention: Crossmodal and Cognitive Effects |
761 |
Jeong & Kim |
Social and emotional biases increase with monetary incentives through attentional inhibition |
| 762 |
Canto-Pereira, Azevedo, & Ranvaud |
The influence of odor on perception of emotional stimuli |
| 763 |
Valdes, Patterson, Shelton, Spanier, Tuladhar, & Buswell |
How's my hat? Effect of emotional expression |
| 764 |
Fallah, Krayz, & Jordan |
Do the hands shift the eyes? |
| 765 |
Jain, Papathomas, & Sally |
Endogenous selective attention to opposite-moving spectral components influences aftereffects in vision and audition |
| 766 |
Sosa, Simon-Dack, Teder-Salejarvi, & McCourt |
A comparison of spatial attention and representation in vision and audition |
| Attention: Selection and Modulation 2 |
767 |
Wyart & Tallon-Baudry |
Neural dissociation between visual awareness and spatial attention |
| 768 |
Kuhn |
Misdirecting people's attention: What can misdirection tell us about attention and awareness? |
| 769 |
Schneider, Hurwitz, Merrifield, & Danckert |
It's about time: why right spatial neglect is mild |
| 770 |
van Zoest, Hickey, & Di Lollo |
The effects of stimulus-salience in object-substitution masking |
| 771 |
Hirose & Osaka |
Asymmetry in object substitution masking occurs relative to the direction of spatial attention shift |
| 772 |
Li & Itti |
Visual attention guided video compression |
| 773 |
Smith & Henderson |
Attentional synchrony in static and dynamic scenes |
| 774 |
Reijnen & Opwis |
Visual search in children with ADHD: The influence of feedback on selective attention |
| 775 |
Menneer, Li, Stroud, Butler, Cave, & Nick |
The effect of practice on top-down guidance in visual search for two types of complex target: Evidence from eye-movements |
| 776 |
Leonard, Moher, & Egeth |
Finding top-down guidance in singleton search: An exploration of critical conditions |
| 777 |
McMains & Kastner |
Collinear alignment modulates competitive interactions in human extrastriate cortex |
| 778 |
Shalev, Mevorach, & Tsal |
The various attention deficits in adult-ADHD and their relation to driving behavior |
| 779 |
Olk |
More than the sum of the parts: Further evidence for an interaction principle of attention |
| 780 |
Ristic, Bonura, & Giesbrecht |
(More) evidence that nonpredictive arrows elicit reflexive orienting: An ERP study |
| 781 |
Smith, Grabowecky, & Suzuki |
A surprisingly stimulus-specific effect of self-awareness on perception of mirrored and un-mirrored self-faces |
| 782 |
Wilson & Gilbert |
Effect of perceptual load on response control |
| 783 |
Buonocore & McIntosh |
Holding up the eyes, not the hands: The effect of remote distractors on reaction times |
| 784 |
Cosman & Vecera |
The perceptual fate of onsets: Abruptly appearing objects are perceived better |
| 785 |
Swallow & Jiang |
The effect of target detection on visual long-term memory for background scenes |
| Binocular Rivalry and Integration 2 |
786 |
Brascamp, Pearson, Blake, & van den Berg |
Slow changes in neural state mediate percept switches in intermittent binocular rivalry |
| 787 |
Kang & Blake |
A novel technique for generating perceptual waves during binocular rivalry and binocular fusion |
| 788 |
Nichols & Wilson |
Factors in the measurement of interocular inhibition fields |
| 789 |
Moradi & Heeger |
Binocular integration and normalization in primary visual cortex: An fMRI study |
| 790 |
Carmel, Walsh, Lavie, & Rees |
A causal role for right parietal cortex in binocular rivalry demonstrated with TMS |
| 791 |
Waterston & Pack |
Enhanced depth perception following high-frequency repetitive transcranial magnetic stimulation of human area V2/V3 |
| 792 |
Aedo-Jury & Pins |
Magnocellular and parvocellular pathways differentially modulate conscious perception with eccentricity: Evidence from binocular rivalry |
| 793 |
Scholvinck & Rees |
Neural correlates of motion-induced blindness in the human brain |
| 794 |
van Ee |
Early neural interactions can explain perceptual bi-stability modifications of stimulus timing, perceptual history, cross-modal influence and attentional control |
| 795 |
Yang & Yeh |
Sound enhances processing of emotional words under invisible conditions |
| 796 |
Yehezkel & Polat |
Meridional asymmetry of collinear interactions in the normal visual cortex |
| 797 |
Marlow & Gillam |
The stimulus conditions for uniocular determination of perceived direction near unpaired regions |
| 798 |
Bharadwaj & Candy |
Accommodative and vergence responses to conflicting blur and disparity cues in the developing visual system |
| 799 |
Hong & Blake |
Channel-specific, monocular adaptation to dynamic Mondrian patterns revealed during binocular rivalry |
| 800 |
Hsu & Yeh |
Is motion-induced blindness a perceptual scotoma? |
| 801 |
Hugrass, Crewther, & Alais |
The effects of motion on binocular rivalry between simple and complex images |
| Receptive Fields and Maps |
802 |
Cope, Blakeslee, & McCourt |
Structural theorems for simple cell receptive fields |
| 803 |
Bressler & Silver |
The effects of spatial attention and population receptive field size estimation on fMRI topographic mapping signals |
| 804 |
Schumacher & Olman |
7T spin echo sequences provide improved spatial accuracy in BOLD fMRI experiments |
| 805 |
Hoffmann, Kanowski, & Speck |
Retinotopic mapping of the human visual cortex at 7 Tesla magnetic field strength |
| 806 |
Keith, DeSouza, Yan, Wang, & Crawford |
A new method for determining neuron receptive field reference-frames |
| 807 |
Masuda, Dumoulin, Nakadomari, & Wandell |
V1 lesion projection zone signals in a subject with tunnel vision |
| 808 |
Mullen, Thompson, & Hess |
Response of the human LGN to different temporal frequencies for achromatic, L/M opponent and S-cone opponent stimuli measured with high field fMRI |
| 809 |
Casanova, Piché, & Ouellette |
Spatiotemporal properties of LP-pulvinar visual receptive fields |
| 810 |
Tsui & Pack |
A simple model of motion integration in primate visual area MT |
| 811 |
Perrone & Krauzlis |
Not so fast there: A re-examination of the pattern versus component classification system used to distinguish Middle Temporal (MT/V5) neurons |
| 812 |
Pack, Churan, & Guitton |
Application of reverse correlation to the study of visual and extraretinal signals in the macaque superior colliculus |
| 813 |
Sachs, Khayat, & Julio |
Contribution of spike timing in contrast and motion direction coding by single neurons in macaque area MT |
| 814 |
Wu, Tiesinga, Tucker, Heiner, & Fitzpatrick |
The dynamics of V1 population response to instantaneous changes in direction of stimulus motion |
| 815 |
Palmer & Seidemann |
Choice probability and reaction-Time correlations in Macaque V1 |
| Processing in Time and Space |
816 |
Cantor & Schor |
A new temporal illusion occurring early in the visual system |
| 817 |
Ogmen, Herzog, & Aydin |
Dynamics of non-retinotopic form perception revealed by a masking paradigm |
| 818 |
Hunt & Cavanagh |
Clocking saccadic remapping |
| 819 |
Morrone, Binda, & Burr |
Spatiotopic selectivity for location of events in space and time |
| 820 |
Ward, Arend, & Rafal |
Spatial and temporal binding in the human pulvinar |
| 821 |
Georgeson & Wallis |
Seeing light vs dark lines: psychophysical performance is based on separate channels, limited by noise and uncertainty |
| 822 |
Thompson |
Does my butt look big in this? Horizontal stripes, perceived body size and the Oppel-Kundt illusion |
| Perceptual Organization 2 |
823 |
Gillam, Anderson, & Seizova-Cajic |
Factors influencing perceived occlusion between amodally completable objects |
| 824 |
Kikuchi & Saito |
Interaction between local and global border-ownership signals on a closed figure composed of small triangles |
| 825 |
Kimchi & Peterson |
Figure-ground segmentation can occur without attention |
| 826 |
Brooks & Driver |
Putting figure-ground organization and perceptual grouping in context |
| 827 |
Tong & Kamitani |
Decoding orientation-selective responses to real and illusory contours |
| 828 |
Francis |
Cortical dynamics of figure-ground segmentation: Shine-through |
| Vision for Action |
829 |
Shmuelof, Hertz, & Zohary |
Mirror-like representation of observed actions |
| 830 |
Peterzell |
The phantom pulse effect: Rapid left-right mirror reversals evoke unusual sensations of phantoms, movements, and paresthesias in the limbs and faces of normals and amputees |
| 831 |
van Mierlo, Brenner, Louw, & Smeets |
Are latency differences between slant cues visible in the online control of our movement? |
| 832 |
Nardini, Jones, Bedford, & Braddick |
Development of optimal integration for self-motion and landmark cues in human navigation |
| 833 |
Bruggeman & Warren, Jr. |
Optic flow recalibrates the direction of walking but not throwing |
| 834 |
MacNeilage & Angelaki |
Visual and vestibular discrimination of heading azimuth and elevation for upright and side-down observers |
| 835 |
Cohen, Cinelli, & Warren |
A dynamical model of pursuit and evasion in humans |
| Object Perception 2 |
836 |
James & Mueller |
Self-generated rotations of 3D objects during initial learning results in automatic motor cortex recruitment during subsequent visual recognition |
| 837 |
Balas & Sinha |
A speed-dependent inversion effect in dynamic object matching |
| 838 |
Cheung, Hayward, & Gauthier |
Dissociating the effects of viewpoint disparity and image similarity in mental rotation and object recognition |
| 839 |
Hammer, Brechmann, Ohl, Diesendruck, Weinshall, & Hochstein |
Differential learning processes for categorization |
| 840 |
Almeida, Mahon, Nakayama, & Caramazza |
Categorical priming: using continuous flash suppression in an object categorization task |
| 841 |
Elazary & Itti |
A bayesian model of visual search and recognition |
| 842 |
Lupyan & Spivey |
Auditory but not visual cues facilitate visual object detection |
| 3D Stereopsis and Motion |
843 |
O'Kane & Hibbard |
Contextual disparity variation does not influence distance scaling in a three-dimensional shape judgement task |
| 844 |
van der Kooij & te Pas |
Contextual bias of slant perception in unreliable context |
| 845 |
Preston, Kourtzi, & Welchman |
Context shapes estimation of 3D structure in human visual cortex |
| 846 |
Liu, Bovik, & Cormack |
Relationship between the Helmholtz shear of vertical meridians and disparity statistics in natural scenes |
| 847 |
Creem-Regehr, Kunz, & Thompson |
Comparing perceived affordances to size and distance estimates in a virtual environment |
| 848 |
Gilson, Fitzgibbon, & Glennerster |
An fully automatic technique for Head Mounted Display calibration |
| 849 |
Svarverud, Gilson, & Glennerster |
Absolute and relative cues for distance investigated using immersive virtual reality |
| 850 |
Cao, Grossberg, & Zaydens |
A laminar cortical model of stereopsis and 3D surface perception of complex natural scenes |
| 851 |
Shah, Domini, & Caudek |
Depth from motion and/or disparity in natural and simulated environments: Do cues-to-flatness matter? |
| 852 |
Czuba, Rokers, Cormack, & Huk |
Mechanisms of 3D motion: Integration of disparity and motion cues |
| 853 |
Gerbino & Fantoni |
Interposition, minimal depth, and depth-from-disparity |
| 854 |
Fernandez & Farell |
A new theory of structure-from-motion perception |
| 855 |
Meng & Zaidi |
Interactions between eye-movements and prior assumptions for 3-D shape from motion |
| 856 |
Greenwald & Knill |
Cue integration outside central fixation: A study of grasping in depth |
| 857 |
LeClair & Durgin |
Depth interval perception: Comparing binocular stereopsis with motion parallax in "action space" |
| 858 |
Hanssens, Piponnier, & Faubert |
Influence of central and peripheral visual field on the postural control when viewing an optic flow stimulus |
| 859 |
Crabtree, Norman, Bartholomew, & Ferrell |
Aging and the perception of slant from optical texture, motion parallax, and binocular disparity |
| 860 |
Norman & Bartholomew |
The effects of sex and age upon the perception of 3-D shape from deforming and static boundary contours |
| Attention: Interactions with Memory |
861 |
Carlisle, Boucher, & Woodman |
Strategic interactions between visual working memory and perceptual attention as revealed by eye movements |
| 862 |
Bettencourt & Somers |
Correlations between visual short-term memory and attentional capacity limits |
| 863 |
Becker |
Attentional bias toward items in working memory: Early but not reflexive |
| 864 |
Ahn & Lleras |
Executive working memory load does not interfere with the rapid resumption of an interrupted visual search |
| 865 |
Emrich, Al-Aidroos, Pratt, & Ferber |
The search for memory: Visual short-term memory capacity predicts performance during visual search tasks |
| 866 |
Huang & Sekuler |
An unattended stimulus attribute leaves its mark on short-term visual memory |
| 867 |
Tan |
The role of visual working memory in object-based attentional selection |
| 868 |
Kristjansson, Ingvarsdottir, & Teitsdottir |
Object- and feature-based priming in visual search |
| 869 |
Brooks, Rasmussen, & Hollingworth |
The interaction between global and local scene features in contextual cueing |
| 870 |
Ogawa & Watanabe |
Implicit learning of attentional guidance modulates visual preference |
| 871 |
Yagi & Kikuchi |
The effect of previously exposed configurations on the affective ratings and the difficulty ratings of target detection |
| 872 |
Hidalgo-Sotelo & Oliva |
Search is enhanced with visual abstinence: Delaying initial saccade latency in familiar scenes improves search guidance |
| 873 |
Im & Chong |
How many mean sizes can we represent? |
| 874 |
Leber & Kawahara |
Abstract learning of attentional set |
| 875 |
Rizzo, Dawson, Anderson, Uc, & Jang |
Awareness of visual impairment in mild AD |
| 876 |
Sheth, Nguyen, & Janvelyan |
How sleep influences our memory for faces |
| Attention: Theoretical and Computational Models |
877 |
Alvarez & Franconeri |
The magical number 4 in visual cognition |
| 878 |
Vul, Hanus, & Kanwisher |
Selective attention and uncertainty |
| 879 |
Peters & Itti |
The role of Fourier phase information in predicting saliency |
| 880 |
Fukuchi & Koch |
The focus of expansion acts as a cue for visual attention |
| 881 |
Drew, Chubb, Ehrlich, Rubin, & Sperling |
Binary versus graded filters for selectively attending to dots of different contrasts |
| 882 |
Wagatsuma, Shimizu, & Sakai |
Contrast modulation by spatial attention for the perception of figure directions |
| Faces: Wholes, Part, Configurations and Features |
883 |
Wong, Palmeri, & Gauthier |
Individuation training but not categorization training leads to configural processing of non-face objects |
| 884 |
Richler, Bukach, & Gauthier |
Context influences holistic processing of face and non-face objects in the composite task |
| 885 |
Orban de Xivry, Ramon, Lefèvre, & Rossion |
Abnormal eye fixations on personally familiar faces following acquired prosopagnosia reveal a lack of individual holistic face perception |
| 886 |
Ramon & Rossion |
Personally familiar faces and holistic processing |
| 887 |
Cornes, Wenger, & Donnelly |
Using general recognition theory to investigate the Thatcher illusion |
| 888 |
Sullivan, Wenger, Von Der Heide, & Bittner |
The crowding effect and perceptual and decisional holism in the visual processing of faces |
| 889 |
Perry, Blaha, & Townsend |
Reassessing the architecture of same-different face judgments |
| 890 |
Ashraf, Sekunova, & Barton |
Discrimination, bias and focused attention in the composite face effect |
| 891 |
Konar, Bennett, & Sekuler |
The composite face effect is still not correlated with face identification accuracy |
| 892 |
Kealey, Sekuler, & Bennett |
Effects of viewing condition and age on the functionality of eye movements for face recognition memory |
| 893 |
Bennett, Pachai, & Sekuler |
Classification images measured in a same/different face discrimination task |
| 894 |
Peterson, Cox, & Eckstein |
The use of the eyes for human face recognition explained through information distribution analysis |
| 895 |
Hill & Scase |
Removing individual features from famous faces: The development of a novel test |
| 896 |
Paras, Rajewale, Tyler, & Webster |
Faces in noise |
| 897 |
Cherian, Morash, & Sinha |
Time-costs for recognizing degraded images |
| 898 |
Kwon, Kalia, & Legge |
Blurry faces are sometimes recognized better than high-resolution faces |
| 899 |
Gottesman |
Don't blink, you are being watched: Effects of direct gaze on attentional blink |
| 900 |
Anes, Short, & Storer |
Hemispheric specialization for face processing revealed by use of Thatcherized and feature distorted faces |
| Motion: Biological Motion |
901 |
Gurnsey, Ouhnana, & Troje |
Perception of biological motion across the visual field |
| 902 |
Jiang & He |
Neural encoding of walking direction in biological motion: Evidence from direction-specific adaptation and functional neuroimaging |
| 903 |
Hussey & Thompson |
Gait-specific adaptation depends on body configuration |
| 904 |
Matsuzaki & Kitazaki |
The perceived depth affects biological motion perception |
| 905 |
Legault & Faubert |
Biological motion perception: Walker distance does not matter |
| 906 |
Thompson, Trafton, McCurry, & Francis |
Perceptions of an animated figure as a function of movement naturalness: No sign of the uncanny valley |
| 907 |
Thurman, Pyles, Troje, & Grossman |
Critical temporal windows for natural point-light gender discrimination |
| 908 |
Jardine, Pyles, & Grossman |
Action invariance: An fMRI investigation of biological motion specificity in the STSp |
| 909 |
Pyles & Grossman |
Biological motion and social interaction activate distinct regions of the sts |
| 910 |
Roether, Omlor, & Giese |
Distinctive postural and dynamic features for bodily emotion expression |
| 911 |
Chang & Troje |
The local inversion effect in biological motion perception is acceleration-based |
| 912 |
Holland, Mody, & Troje |
Person identification across actions from biological motion |
| 913 |
Williamson, Jakobson, & Troje |
A right-facing bias in the processing of biological motion? |
| 914 |
Senkfor |
Perceptual biases expressed during observation of human movement |
| 915 |
Ikeda & Watanabe |
Recognizing emotional states from biological motion within noise |
| Saccadic Eye Movements |
916 |
Baker & Adler |
Saccadic reaction times and speed of information processing development |
| 917 |
Gegenfurtner, Schütz, & Schneider |
Saccadic gain adaptation follows perceived position |
| 918 |
Stritzke, Trommershäuser, & Gegenfurtner |
Optimality of saccadic decisions under risk |
| 919 |
Madelain, Paeye, & Wallman |
Saccadic adaptation: reinforcement can drive motor adaptation |
| 920 |
Panouillères, Cotti, Guillaume, Urquizar, Salemme, Munoz, & Pélisson |
Adaptation of saccadic eye movements: behavioural evidence for different mechanisms controlling saccade amplitude lengthening and shortening |
| 921 |
Pélisson, Panouillères, Alahyane, Urquizar, Salemme, & Tilikete |
Adaptation of saccadic eye movements: neurological evidence for different mechanisms controlling the amplitude of reactive and voluntary saccades |
| 922 |
Herman, Harwood, & Wallman |
Saccadic gain adaptation can depend on the visual context |
| 923 |
Rodriguez, Lee, Koehn, van Zoest, & Barton |
Previous saccades to other locations affect the programming of current antisaccade coordinates, but not those of prosaccades |
| 924 |
Gerardin, Gaveau, Pelisson, & Prablanc |
Reactive saccades dynamics: Visual integration and visual context |
| 925 |
Edelman & Xu |
Visuomotor set can suppress the inhibitory influence of distractors on express saccades |
| 926 |
Zhang, Cantor, & Schor |
Luminance and saccadic supression on perisaccadic spatial distortions |
| 927 |
Knöll, Beyer, & Bremmer |
Spatio-temporal topography of saccadic suppression |
| 928 |
Pola |
Perisaccadic visual compression shown by target-flash mislocalization may be affected by flash visual persistence interacting with background stimuli |
| 929 |
Savina, Bergeron, & Guitton |
A visual target in the blind hemifield of hemidecorticate patients reduces latency and improves accuracy of antisaccades |
| 930 |
Chahine & Krekelberg |
Cortical contributions to saccadic suppression |
| 931 |
Otero-Millan, Leigh, Serra, Troncoso, Macknik, & Martinez-Conde |
Objective characterization of square-wave jerks in progressive supranuclear palsy patients and healthy volunteers |
| 932 |
Pratt, Al-Aidroos, Campbell, & Hasher |
Older adults just can't look away: Age-related changes in saccadic trajectory curvature |
| 933 |
Sadr, Allison, Vinnikov, & Swierad |
Influence of relative saccade direction on detection of transsaccadic natural scene transitions |
| 934 |
Wu, Schnitzer, Kowler, & Pizlo |
Fitts's Law and the optimal planning of sequences of saccades |
| 935 |
Cristino & Baddeley |
The which and the where of eye movement control |
| Spatial Vision: Mechanisms 2 |
936 |
Gheorghiu, Kingdom, & Witney |
Size and shape-frequency after-effects: same or different mechanism? |
| 937 |
Kingdom & Watt |
An after-effect of perceived length |
| 938 |
Vera-Diaz, Goldstein, & Peli |
Asymmetrical adaptation to highpass versus lowpass filtered images |
| 939 |
Lesmes, Lu, Baek, & Albright |
Efficient adaptive measurement and classification of contrast sensitivity functions |
| 940 |
Chubb & Wright |
Diverse long range configural judgments use a single map of object locations |
| 941 |
Haxhimusa, Pizlo, & Catrambone |
Non-Euclidean visual traveling salesman problem |
| 942 |
Garcia-Suarez, Ruppertsberg, & Bloj |
Visual sensitivity to achromatic gradients with different luminance profiles |
| 943 |
Hibbeler & Olzak |
Psychophysically defined gain control pool and summing circuit bandwidths for orientation selective pathways |
| 944 |
Park & Chong |
Representation of mean spatial frequency |
| 945 |
Petrov & Meleshkevich |
Mega surround suppression: A synergy between target pedestal and surround mask |
| 946 |
Sahraie, Griffiths, & Conway |
Comparison of pupil responses to the first and second order gratings |
| 947 |
Roach & McGraw |
Time course of motion-induced shifts in perceived position |
| 948 |
Squire, Greenwood, & Parasuraman |
Are shifting, splitting, and scaling of attention similar processes? |
| 949 |
Stringham, Smith, & McLin |
Visual performance and glare: Spatial properties of visual obscuration |
| 950 |
Yellott |
Precorrecting visual objects destined for defocus |
| 951 |
Żychaluk & Foster |
Resolving inconsistencies between parametric estimates of psychometric functions by nonparametric fitting |
| 952 |
Tibber, Elaine, Rees, & Morgan |
The neural correlates of the 3-dot vernier task: Visuospatial extrapolation examined within the framework of a duplex model of vision |
| 953 |
Tsuruhara, Kanazawa, & Yamaguchi |
Effects of reference frame on the perception of human-body orientation in infancy |
| 954 |
Koene, Huang, & Chen |
Percept dependent acitivity in the occipitotemporal cortex for Ebbinghaus illusion |
| Visual Pathways: Receptors to Cortex |
955 |
Reeves & Grayhem |
Early scotopic dark adaptation; change in noise alone? |
| 956 |
Ripamonti, Crowther, & Stockman |
The S-cone luminance input depends on the level of M-cone adaptation |
| 957 |
Hess, Mullen, Thompson, & Gole |
LGN abnormalities in human amblyopes revealed by high-field fMRI |
| 958 |
Sherbondy, Dougherty, & Wandell |
Identification of optic radiation in-vivo using diffusion tensor imaging and fiber tractography |
| 959 |
Grueschow, Rieger, Stadler, Tempelmann, Heinze, Speck, & Haynes |
Topography of responses to colour and luminance in human subcortical visual pathways as revealed by high-resolution fMRI at 7T |
| 960 |
Boyaci, Fang, Murray, Albanese, & Kersten |
Time course of cortical responses to illusory and real lightness changes |
| Face Perception: Emotion and Experience |
961 |
Hammal, Tsuchiya, Adolphs, Arguin, Schyns, & Gosselin |
What does the activity in the amygdala and the insula correlate with in fearful and disgusted faces |
| 962 |
Tsuchiya, Kawasaki, Howard, & Adolphs |
Decoding frequency and timing of emotion perception from direct intracranial recordings in the human brain |
| 963 |
Garrod, Smith, & Schyns |
Classification maps: An information-theoretic technique for relating cortical activity to stimulus information in a facial expression categorization task |
| 964 |
Wilbraham, Christensen, Todd, & Martinez |
The effect of homeomorphic image transformations on face matching performance |
| 965 |
Afraz, Vaziri-Pashkam, & Cavanagh |
Local gender biases in face appearance across the visual field |
| 966 |
Hsiao & Cottrell |
Perception of Chinese characters in novices' and experts' eyes: Similarities and differences between face and Chinese character recognition |
| Spatial Vision: Crowding and Eccentricity 2 |
967 |
Knight, Shapiro, & Lu |
Drastically different percepts of five illusions in foveal and peripheral vision reveal their differences in representing visual phase |
| 968 |
Chakravarthi & Pelli |
What role does contour integration play in crowding? |
| 969 |
Nandy & Tjan |
The origin of crowding zones |
| 970 |
Chung, Tjan, & Lin |
Feature maps for letters |
| 971 |
Vickery, Shim, Jiang, Chakravarthi, & Luedeman |
Supercrowding: Weakly masking a target greatly enhances crowding |
| 972 |
Rosen, Chakravarthi, & Pelli |
Nasotemporal asymmetry of acuity and crowding |
| 973 |
Liu, Jiang, & He |
Reduction of the crowding effect in spatially adjacent but cortically remote visual stimuli |
| Perceptual Learning 1 |
974 |
Censor & Sagi |
Practice little, gain much: Short training enables long-term resistance to perceptual deterioration |
| 975 |
Barthelmé & Mamassian |
Learning confidence in a visual task |
| 976 |
Kim, Seitz, & Shams |
Neural mechanisms of multisensory perceptual learning |
| 977 |
Lu, Xu, Wang, Dosher, Zhou, Zhang, & Zhou |
Category and perceptual learning in subjects with treated wilson's disease |
| 978 |
Jeter, Dosher, Lu, & Bi |
Simultaneous training of two high precision tasks is largely independent even when orientation or position is shared |
| 979 |
Schwarzkopf & Kourtzi |
Learning against the natural statistics: Experience-dependent plasticity for contour detection in the human visual cortex |
| 980 |
Shibata, Ishii, Yamagishi, & Kawato |
Boosting perceptual learning by feedback manipulation |
| Attention: Costs of Divided Attention |
981 |
Scharff & Palmer |
Distinguishing serial and parallel models using variations of the simultaneous-sequential paradigm |
| 982 |
Maeda & Nagy |
Attentional resources and the parvocellular and magnocellular pathways |
| 983 |
Somers & Sheremata |
Cross-hemifield attention benefits for visual enumeration |
| 984 |
Huang, Pashler, & Treisman |
Testing a theory of visual attention |
| 985 |
Montagna, Pestilli, & Carrasco |
Trading off visual acuity? Transient attention increases acuity at cued locations and decreases it at uncued locations |
| 986 |
Mordkoff & Halterman |
Coactivation occurs within objects, not between dimensions |
| 987 |
Stojanoski & Niemeier |
Neural basis of feature cueing in the perception of object contours |
| 988 |
Wenger & Fitousi |
Testing Lavie's (1995) perceptual load theory |
| 989 |
Highsmith, Duncan, O'Neil, Roth, & Crognale |
Effects of selective attention on the chromatic VEP: Task-relevant stimuli |
| Attention: Neural Mechanisms |
990 |
Arcizet & Bisley |
The effect of a top-down cue on spread attention in the macaque |
| 991 |
Mirpour, Arcizet, & Bisley |
Dynamics of the priority map in LIP during visual search |
| 992 |
Itti, Yoshida, Berg, Ikeda, Kato, Takaura, & Isa |
Saliency-based guidance of gaze in monkeys with unilateral lesion of primary visual cortex |
| 993 |
Beck & Torralbo |
Perceptual load-induced selection as a consequence of spatial interactions in visual cortex |
| 994 |
Jehee, Brady, & Tong |
Attention improves decoding of stimulus orientation in early visual areas |
| 995 |
Niemeier, Le, & Stojanoski |
Contrast-specific neural responses underlying the perceptual bias |
| 996 |
Scolari & Serences |
Estimating the shape of the feature-based attentional gain function |
| 997 |
Zhaoping |
Strong exogenous attraction to attention by unique eye of origin --- evidence for a bottom-up saliency map in the primary visual cortex |
| 998 |
Arita & Woodman |
Do gamma-band oscillations bind features when attention is focused on multiple-feature objects during visual search? |
| 999 |
Bogler & Haynes |
Retinotopically independent processing of saliency signals in the near-absence of attention |
| 1000 |
Hogendoorn, Carlson, Gebuis, & Verstraten |
N200 latency predicts behaviorally measured attentional shift time |
| 1001 |
Arcaro, McMains, & Kastner |
Phase-encoded attention tasks reveal topographic maps in posterior parahippocampal cortex |
| 1002 |
Kim, Grabowecky, Paller, & Suzuki |
Selective lateralization of steady state visual evoked potentials at the second harmonic |
| 1003 |
Lennert, Jolicoeur, Cheyne, & Martinez-Trujillo |
MEG responses in the human brain during the selection of visual targets |
| 1004 |
Mathewson, Gratton, Fabiani, Beck, & Ro |
Pre-stimulus activity predicts subsequent target detection in meta-contrast masking |
| 1005 |
Chiu, Esterman, & Yantis |
Decoding cognitive control in the parietal cortex |
| 1006 |
Lomber, Woller, Hall, & Payne |
Neglected sight: Preserved visual functions within a neglected hemifield |
| Perceptual Organization: Grouping and Segmentation |
1007 |
Salvagio, Mojica, & Peterson |
Context effects in figure-ground perception: The role of biased competition, suppression and long-range connections |
| 1008 |
Allen, Humphreys, & Colin |
Ventral extra-striate visual regions, feedback and texture perception |
| 1009 |
Otsuka, Yamazaki, Konishi, Kanazawa, Yamaguchi, & Spehar |
Perception of illusory transparent surface by young infants |
| 1010 |
Thompson, Olman, & Kersten |
V1 BOLD response to image regions defined by 1st and 2nd order luminance contrast |
| 1011 |
Weil & Rees |
Perceptual filling-in of an artificial scotoma shows retinotopic specificity in human visual cortex |
| 1012 |
Harrison & Feldman |
Influence of medial axis structure on the discrimination of texture-defined shapes |
| 1013 |
Ghose & Palmer |
Edge alignment effects for gradient cuts in figure-ground organization |
| 1014 |
Juni, Singh, & Maloney |
Testing for robustness in visual localization of dot clusters without part structure |
| 1015 |
Treder & van der Helm |
Redundancy enhances the integration of symmetry information |
| 1016 |
Nelson |
Perceptual organization in autism and asperger syndrome |
| 1017 |
Devyatko & Falikman |
Would letters forming a word survive motion-induced blindness? |
| 1018 |
Franconeri & Bemis |
Similarity grouping is feature selection |
| 1019 |
Greenberg & Yantis |
An objective measure of the relative strength of perceptual grouping cues using object-based attention |
| 1020 |
Hock & Nichols |
State-dependent dynamic grouping and the perception of motion |
| 1021 |
Leveille, Grossberg, Mingolla, & Versace |
Perceptual grouping in a spiking laminar cortical model |
| 1022 |
Hein, Moore, & Palmer |
Perceptual structure facilitates spatial filtering |
| Motion: Spatial Interactions and Aftereffects |
1023 |
Tsotsos, Sekuler, & Bennett |
The effects of aging on the bandwidths of directionally-selective mechanisms |
| 1024 |
Bower, Zheng, Ni, & Andersen |
The effect of retinal eccentricity on the discrimination of global motion direction |
| 1025 |
Sheliga, FitzGibbon, & Miles |
Local and global inhibitory influences associated with large-field stimuli |
| 1026 |
Dakin, Apthorp, & Alais |
Judgment of absolute direction in natural scenes |
| 1027 |
Greenwood & Edwards |
Seeing multiple global directions: A maximum capacity limit of three |
| 1028 |
Champion & Freeman |
Access to retinal image movement during pursuit eye movement is only direct at high motion coherence |
| 1029 |
Golomb, Ruf, Beck, Saricicek, Hu, Chun, & Bhagwagar |
Diminished center-surround inhibition in patients with a history of depression |
| 1030 |
Rokem, Sanghvi, & Silver |
A model of V1-to-MT connectivity accounts for motion perception anisotropies in the human visual system |
| 1031 |
Shioiri, Matsumiya, & Tamura |
Static and flicker MAE for global motion |
| 1032 |
von Grünau, Engarhos, & Bacchus |
Motion aftereffect and motion fading: Same underlying mechanisms? |
| 1033 |
Curran, Clifford, & Benton |
Adaptation precedes inhibition for motion direction interactions |
| 1034 |
Iordanova-Maximov & von Grunau |
Visual velocity aftereffects in radial flow: Inherited and unique features |
| 1035 |
Patterson, Rogers, Boydstun, Tripp, & Stefik |
System dynamics modeling of the optic flow motion aftereffect |
| 1036 |
Nakajima & Sato |
The involvement of local motion adaptation in global motion aftereffect |
| 1037 |
Gepshtein, Tyukin, & Albright |
Making sense of motion adaptation |
| Perception and Action: New Issues |
1038 |
Nijboer, Gebuis, Plukaard, de Haan, & van der Smagt |
Neural mechanisms underlying grapheme-colour synesthesia |
| 1039 |
Gorea, Mamassian, & Kaing |
Duration estimation of one's own reactive and proactive motor responses |
| 1040 |
Jagadeesh, Liu, & Brunet |
Implicit measurement of uncertainty during classification of ambiguous photographs |
| 1041 |
Seeley & Waughtel |
Motor simulation & the effects of energetic & emotional costs of depicted actions in picture perception |
| 1042 |
Twedt, Linkenauger, Banton, & Proffitt |
The effect of biking effort on perceived distance and slant |
| 1043 |
Siegle, Campos, Mohler, Loomis, & Buelthoff |
High-precision capture of perceived velocity during passive translations |
| 1044 |
Stone, Dolgov, DaSilva, & McBeath |
Basketball free throw accuracy unaffected by projected background displays showing motion or emotion |
| 1045 |
Tversky & Geisler |
Spatiotemporal statistics of motion through natural environments |
| 1046 |
Kitazaki & Kimura |
Frequency-phase analysis of postural sway induced by visual motion and galvanic vestibular stimulation |
| 1047 |
Kalia, Schrater, Legge, & Kallie |
Estimating absolute distances with blurred vision |
| 1048 |
Coakley & Wolfe |
A dissociation between haptic and visual distortion of perceived length |
| 1049 |
Short & Ward |
Virtual limbs and body space: The effects of the rubber hand illusion |
| 1050 |
Aloimonos |
HAL: Human Activity Language |
| 1051 |
Anderson, Levine, & McAnany |
Prestidigitation: Easier to fool the eye than the hand |
| 1052 |
Natter & Phillips |
The french drop sleight: Deceptive biological motion |
| 1053 |
Thomas & Lleras |
Moving thought: Directed movement guides insight in problem solving |
| Multisensory Processing: High Level |
1054 |
Vettel, Green, Heller, & Tarr |
The neural representation of dynamic real-world auditory/visual events |
| 1055 |
Prasad, Thomas, & Aguirre |
Cross-modal language processing in the visual cortex of the congenitally blind |
| 1056 |
Geiger, Cattaneo, Lorusso, Galli, Facoetti, Pozzoli, & Molteni |
Auditory recognition in dyslexics improves with visual and motor-visual practice |
| 1057 |
Iordanescu, Grabowecky, & Suzuki |
Characteristic sounds facilitate vigilance when targets are rare in visual search |
| 1058 |
Batson & Watanabe |
Plasticity of crossmodal spatiotemporal effects in a visual search task |
| 1059 |
Mitroff & Jordan |
Videogame players demonstrate enhanced multi-sensory abilities |
| 1060 |
Takahashi, Diedrichsen, & Watt |
The brain integrates visual and haptic information from different spatial locations when using a tool |
| 1061 |
Kao & Goodale |
Enhanced detection of visual stimuli projected on a tool |
| 1062 |
Jenkin, Barnett-Cowan, Dyde, Sanderson, Jenkin, & Harris |
Left/right asymmetries in the contribution of body orientation to the perceptual upright |
| 1063 |
Negishi, Kaneko, & Mizushina |
Integration of the multi-sensory information for the perception of gravitational vertical |
| 1064 |
Balaban, Barnett-Cowan, Sanderson, & Harris |
Blood pressure response to roll depends on both visual and non-visual factors |
| 1065 |
Honma, Koyama, & Osada |
One visual stimulus provides two tactile sensations simultaneously |
| 1066 |
Wu, Klatzky, & Stetten |
Exploring here, seeing where? Visualization with in-situ vs. ex-situ viewing |
| 1067 |
Phillips, Egan, & Perry |
Gawking and fondling: Multimodal perception of 3D shape |
| Search 3 |
1068 |
Haberman & Whitney |
Search for mean(ing): Parallel processes mediate ensemble coding |
| 1069 |
List, van Koningsbruggen, & Rafal |
Visual search after frontal eye field lesions in humans |
| 1070 |
Malcolm & Henderson |
Visual search in real-world scenes: Effects of target cue specificity and cue lead time on component search processes |
| 1071 |
Beck, Lohrenz, Trafton, & Gendron |
The role of local and global clutter in visual search |
| 1072 |
Chan & Hayward |
Dissociating preattentive vision and preattentive attentional guidance |
| 1073 |
Hulleman |
Do T-junctions slow down visual search? |
| 1074 |
Olds, Jones, & Graham |
A colour-orientation asymmetry for priming within a search trial: Previewing features of individual search items immediately before conjunction search |
| 1075 |
Shen & Paré |
Selection and timing of gaze fixations in visual conjunction search |
| 1076 |
Paffen, Hooge, Benjamins, & Hoogendoorn |
Pop-out for interocular conflict |
| 1077 |
Norman-Haignere, Jungé, & Chun |
Rapidly resuming visual search and same/different judgments: The influence of task difficulty and stimulus complexity |
| 1078 |
Tavassoli, van der Linde, Bovik, & Cormack |
Selectivity for multiple orientations in visual search |
| 1079 |
Zhuang & Papathomas |
Feature- and location-based attention in color/orientation conjunctive visual search |
| 1080 |
Purcell, Heitz, Cohen, Logan, Schall, & Palmeri |
Modeling interactions between visually-responsive and movement-related neurons in FEF during saccade visual search |
| 1081 |
Beck, Ma, & Navalpakkam |
Bayesian theory of visual search |
| 1082 |
Lovell, Gilchrist, Tolhurst, To, & Troscianko |
Predicting search efficiency with a low-level visual difference model |
| 1083 |
Ishibashi & Kita |
Effect of subjective probability on search termination |
| 1084 |
Neider, Voss, & Kramer |
Coordinating spatial attention: Using shared gaze to augment search and rescue |
| Binocular Mechanisms 3 |
1085 |
Banks & Schreiber |
Are the positions of corresponding points adaptive for natural viewing? |
| 1086 |
Fukuda, Wilcox, Allison, & Howard |
Comparison of depth percepts created by binocular disparity, Panum's limiting case, and monoptic depth |
| 1087 |
Rogers, Colam, & Cant |
Sensitivity to disparity modulations in ground plane surfaces |
| 1088 |
Chai & Farell |
How does perceived depth depend on disparity direction? |
| 1089 |
Xu, He, & Ooi |
Sensory eye dominance is retinal location specific and affects stereopsis |
| 1090 |
Battaglia, Ernst, Schrater, Di Luca, Machulla, & Kersten |
Humans use stereo and haptic distance cues to improve physical object size estimates |
| Attention to Locations and Features |
1091 |
Tseng, Cameron, Munoz, & Itti |
Differentiating patients from controls based on correlation between salience and gaze |
| 1092 |
Landau & Robertson |
Spatial attention accelerates inter-hemispheric transfer time |
| 1093 |
Saiki & Holcombe |
Surface-based, unpaired feature representations mediate detection of change to feature pairings |
| 1094 |
Schneider & Komlos |
Attention biases decisions but does not alter appearance |
| 1095 |
Carrasco, Rosenbaum, & Giordano |
Exogenous attention: Less effort, more learning! |
| 1096 |
Theeuwes & Belopolsky |
The size of attentional window modulates attentional capture |
| Color Appearance |
1097 |
MacLeod, Pallett, & Krizay |
Are there phenomenal complementaries? |
| 1098 |
Stockman, Smithson, Aboshiha, West, & Ripamonti |
Chromatic appearance depends on the rate of change of the colour signal (the "slew" rate) |
| 1099 |
Hsieh & Tse |
Pattern classification on BOLD signals reveals a novel mechanism underlying color filling-in |
| 1100 |
Foster & Żychaluk |
Predicting illuminant-shifted cone excitations: Superiority of a non-parametric approach over von Kries' coefficient rule |
| 1101 |
Hurlbert, Vurro, & Ling |
Colour constancy of polychromatic surfaces |
| 1102 |
Anstis, Vergeer, & van Lier |
Color averaging linked to contours, textures and orientation |
| Scene Perception 3 |
1103 |
Wolfe, Alvarez, Rosenholtz, Oliva, Torralba, Kuzmova, & Uhlenhuth |
Search for arbitrary objects in natural scenes is remarkably efficient |
| 1104 |
Greene & Oliva |
High-level aftereffects to natural scenes |
| 1105 |
Lorenceau, Paradis, Lamirel, Poline, Artiges, Thirion, & Caclin |
Cortical dynamics of bistable form/motion binding: fMRI and eye movements |
| 1106 |
Stocker & Simoncelli |
A model of self-consistent perception |
| 1107 |
Nuthmann, Smith, & Henderson |
Fixation durations in scene viewing: Experimental data and computational modeling |
| 1108 |
Bridgeman & Tseng |
Change blindness by substituting one natural image with another |
| Attention: Inhibition and Capture |
1109 |
Vallines, Lin, & Müller |
Cortical control of salient-distracter interference during visual search: Can attentional capture be top-down modulated? |
| 1110 |
Adamo, Pun, Pratt, & Ferber |
Spatiotemporal dynamics in inhibition of return |
| 1111 |
Guenther & Brown |
Influences of abrupt vs. ramped stimulus presentation on location-based inhibition of return |
| 1112 |
Johnson, Fallah, & Jordan |
Object- and location-based inhibition of return to superimposed surfaces |
| 1113 |
Levinthal & Lleras |
Simultaneous feature-based inhibition of attention along multiple dimensions |
| 1114 |
Chu, Levinthal, & Lleras |
Semantic marking in preview search |
| 1115 |
Oosugi, Kumada, & Kawahara |
The spatial distribution of visual marking |
| 1116 |
Olivers |
What drives memory-driven attentional capture? |
| 1117 |
Fukuda & Vogel |
Individual differences in resistance to attentional capture |
| 1118 |
Inukai, Kumada, & Kawahara |
Attentional capture is reduced when distractors remain visible in rapidserial visual presentation |
| 1119 |
Moher, Egeth, Yantis, & Stuphorn |
Top-down control modulates the effect of capture based on distractor probability |
| 1120 |
Sawaki & Katayama |
Modulation of attentional capture for distractor object in serial presentation paradigm |
| 1121 |
Wang & Most |
Is contingent attentional capture not contingent on working memory? |
| 1122 |
Yeshurun, Kimchi, Sha’shoua, & Carmel |
Perceptual objects capture attention |
| Perceptual Learning 3 |
1123 |
Huang, Lu, & Dosher |
Co-learning analysis of two perceptual learning tasks with identical input stimuli supports the reweighting hypothesis |
| 1124 |
Liu, Lu, & Dosher |
Augmented Hebbian Learning Hypothesis in Perceptual Learning: Interaction between feedback and training accuracy |
| 1125 |
Huang, Lu, Zhou, & Liu |
Perceptual learning in speed discrimination of radial motion |
| 1126 |
Blaha & Townsend |
A Hebbian-style dynamic systems model of configural learning |
| 1127 |
Tseng & Huang |
Eye-dependent attentional modulation on motion sensitization from speed discrimination |
| 1128 |
Casco, Guzzon, & Campana |
Sleep enables explicit figure-ground segmentation of unattended textures |
| 1129 |
Matarazzo, Maquet, Frankó, & Vogels |
Offline processing of memories induced by perceptual visual learning during subsequent wakefulness and sleep: a behavioral study |
| 1130 |
Åberg, Tartaglia, & Herzog |
Perceptual learning requires a minimal number of trials per session, but no sleep |
| 1131 |
Nyquist, Lappin, & Tadin |
Perceptual training yields rapid improvements in visually impaired youth |
| 1132 |
Hotson, Neary, & Anand |
Perceptual learning is similar across the central visual fields |
| 1133 |
Suchow & Pelli |
Letter learning: Feature detection and integration |
| 1134 |
Husk, Betts, O'Craven, Bennett, & Sekuler |
House training modifies activity in PPA, RSC, but not FFA |
| 1135 |
Hussain, Bennett, & Sekuler |
Contrast-reversal abolishes perceptual learning |
| 1136 |
Yu, Zhang, Kuai, Xiao, Klein, & Levi |
Stimulus coding rules for perceptual learning |
| Faces: Adaptation and Context |
1137 |
Shimojo, Park, Kashino, & Shimojo |
Familiarity for faces and novelty for natural scenes in preference: Does similarity matter? |
| 1138 |
Stoesz & Jakobson |
The influence of processing style on face perception |
| 1139 |
Brewster, Dobrin, Mullin, & Steeves |
Sex, handedness and sexual orientation as predictors of face perception ability |
| 1140 |
Jordan, Johnson, & Fallah |
Dual perceptual adaptation in human faces: Gender and age |
| 1141 |
O'Neil, Webster, & Webster |
Adapting to age |
| 1142 |
Lawson & Calder |
Adaptation reveals multichannel-coded cells tuned to body orientation in humans |
| 1143 |
Oruc & Barton |
Brief adaptation increases sensitivity of face recognition |
| 1144 |
Rostamirad, Oruc, & Barton |
Face space has a center-surround organization: Evidence from a novel contrast-based face-adaptation technique |
| 1145 |
Narvekar, Jiang, Phillips, & O'Toole |
Illumination effects on the inverse relationship between face typicality and recognition |
| Perception and Action: Locomotion and Navigation |
1146 |
Souman, Frissen, & Ernst |
The effect of walking on perceived visual speed depends on visual speed |
| 1147 |
Campos, Siegle, Mohler, Bülthoff, & Loomis |
Imagined self-motion differs from perceived self-motion |
| 1148 |
Kunz, Creem-Regehr, & Thompson |
The influence of relevant action on spatial updating during imagined locomotion |
| 1149 |
Yamamoto & Philbeck |
Little evidence of perceptual depth compression when indicating extents by imagined walking |
| 1150 |
Post & Rutledge |
Adaptation of blind-walking does not influence verbal distance estimates |
| 1151 |
Bakdash, Linkenauger, Stefanucci, Witt, Banton, & Proffitt |
Perceived distance influences simulated walking time |
| 1152 |
Zetzsche, Reineking, Wolter, & Schill |
Active vision for exploratory localization |
| 1153 |
Chrastil & Warren |
Testing models of path integration in a triangle completion task |
| 1154 |
Mingolla, Browning, & Grossberg |
Neural dynamics of visually-based object segmentation and navigation in complex environments |
| 1155 |
Saunders & Durgin |
Adaptation to conflicting visual and physical self-motion information during walking |
| 1156 |
Owens & Warren |
Can people learn to anticipate obstacle motion when necessary to avoid collision? |
| 1157 |
Nadeem, Stankiewicz, & Hayhoe |
Learning a spatial layout: The role of landmark placement and gaze-time |
| 1158 |
Gérin-Lajoie & Warren |
The circumvention of barriers: Extending the steering dynamics model |
| 1159 |
Dyre & Lew |
Environmental modulations of visually-induced steering errors resulting from non-rigid transparent optical flow |
| 1160 |
Peng, Stone, & Li |
Humans can control heading independent of visual path information |
| 1161 |
Cheng, Khuu, & Li |
Implied FOE from form influences human heading perception |
| 1162 |
Li, Stone, & Chan |
Visual control of steering toward a goal uses heading but not path information |
| 1163 |
Franchak, Smith, & Adolph |
Visual guidance of locomotion in infants, young adults, and the elderly |
| Visual Working Memory 2 |
1164 |
Berg & Itti |
Memory, eye position and computed saliency |
| 1165 |
Clark & Garrigan |
The effects of interference on visual memory of 2D shape |
| 1166 |
Karthaus, Demarais, & Roy |
Action and semantic attributes in object identification |
| 1167 |
Martini |
Two memory components explain sequential dependencies in a search task |
| 1168 |
Fecteau & Shapiro |
Multiplying the capacity of visual working memory |
| 1169 |
Fougnie & Marois |
Working memory capacity is modality-specific: Evidence of separate stores for auditory and visuospatial stimuli |
| 1170 |
Meyer, Qi, Stanford, & Constantinidis |
Effects of training on the organization of spatial and feature visual responses in the lateral prefrontal cortex |
| 1171 |
Kibbe |
The complexity of a category affects working memory capacity in a search task |
| 1172 |
Perez & Vogel |
Relating visual working memory capacity and visual attention in schizophrenia-spectrum individuals |
| 1173 |
Sheremata & Somers |
Role of encoding duration on visual-short term memory capacity |
| 1174 |
Wong, Peterson, & Thompson |
Object similarity in visual working memory: A face-specific memory effect |
| 1175 |
Curby & Smith |
Facing fear: The effect of emotional expressions on visual short-term memory for faces |
| 1176 |
Gaunt & Bridgeman |
Microsaccade directions are not correlated with cued locations in a spatial working memory task |
