| Binocular Rivalry |
1 |
Gilroy & Blake |
Negative afterimages generated during binocular rivalry show signs of weakness and signs of strength |
| 2 |
Kim, Blake & Lee |
When a traveling wave meets a gap on its way |
| 3 |
Kitazaki & Mase |
Contrast effect of spatial context on binocular rivalry is modulated by eccentricity and binocular depth |
| 4 |
Meng & Tong |
Binocular rivalry can fully gate the formation of visual phantoms |
| 5 |
Ooi, He & Su |
Binocular rivalry is affected by surface boundary contours |
| 6 |
Paffen, te Pas & Verstraten |
Surround inhibition affects perception of center motion in a manner similar to lowering the center's luminance contrast |
| 7 |
Beintema, Oleksiak & van Wezel |
Structure-from-motion and biological motion perception influences on binocular rivalry |
| 8 |
Breitmeyer, Ogmen & Koc |
Metacontrast and binocular rivalry suppression reveal hierarchies of unconscious visual processing |
| 9 |
Rees & Haynes |
Predicting the stream of human consciousness |
| 10 |
Hong & Shevell |
Perceptual mis-binding of color and form during binocular rivalry |
| 11 |
Duponsel & Overbury |
The effect of ocular dominance and interocular rivalry on monocular reading speed under near-normal, ganzfeld, and complete occlusion conditions |
| 12 |
Maier, Wilke, Logothetis & Leopold |
Perceptual and neuronal dynamics of binocular rivalry flash suppression |
| 13 |
Wilke, Logothetis & Leopold |
Temporal dynamics of generalized flash suppression in V4 |
| 14 |
Crewther & Panayiotou |
Multistable motion rivalry – four co-localised motion directions compete with similar dynamics to binocular motion rivalry |
| 15 |
Fang & He |
Cortical responses to invisible objects in human dorsal and ventral pathways |
| Biological Motion I |
16 |
Gibson, Sadr, Troje & Nakayama |
Perception of biological motion at varying eccentricity |
| 17 |
Ikeda, Blake & Watanabe |
Eccentricity dependency of the biological motion perception |
| 18 |
Zyborowicz & Pinto |
Detection of biological motion in the visual periphery |
| 19 |
Balk, Carpenter, Brooks, Rubinstein & Tyrrell |
The conspicuity of pedestrians at night: How much biological motion is enough? |
| 20 |
Freire, Maurer, Lewis & Blake |
The ups and downs of point-light displays: Sensitivity to upright and inverted biological motion |
| 21 |
Garcia & Grossman |
Perception of point-light biological motion at isoluminance |
| 22 |
Hiris & Cramer |
How much does biological motion perception depend on motion? |
| 23 |
Lu, Yuille & Liu |
Configural processing in biological motion detection: Human versus ideal observers |
| 24 |
Montesanto, Penna, Stara & Boi |
The effect of blurring on action recognition by human subjects |
| 25 |
Oh & Shiffrar |
Multistability of point-light gait is resolved by the optical flow of the ground |
| 26 |
Sigala, Serre, Poggio & Giese |
Learning mid-level motion features for the recognition of body movements |
| Attention, Motion, & Tracking |
27 |
Place & Wolfe |
Multiple visual object juggling |
| 28 |
Fencsik, Horowitz, Place, Klieger & Wolfe |
Target tracking during interruption in the multiple-object tracking task |
| 29 |
Horowitz & Place |
Rapid recovery of targets in multiple object tracking |
| 30 |
Mitchell, Sundberg & Reynolds |
Attentive tracking of multiple objects by humans and monkeys |
| 31 |
Reilly, Pylyshyn & King |
Further evidence for inhibition of moving nontargets in multiple object tracking |
| 32 |
Rein, Pylyshyn & Alvarez |
Using multiple-object tracking (MOT) to test whether cerebral hemispheres share common visual attention resources |
| 33 |
Yoshida & Shioiri |
Object substitution masking during attentive tracking |
| 34 |
Johnson, Curtis & Shuwairi |
Cortical and behavioral manifestations of dynamic object occlusion |
| 35 |
Benjamins, van der Smagt & Verstraten |
The upper temporal limit of attention-based motion perception is increased by an in-phase auditory stimulus |
| 36 |
Freeman |
Attentional control of multi-stable aperture motion |
| Faces 1 |
37 |
Schwarzlose, Baker, Yovel & Kanwisher |
Separate face and body selectivity on the fusiform gyrus |
| 38 |
Mangini & Kanwisher |
Activation in lateral occipital and fusiform cortex predicts performance in threshold face identificaiton tasks |
| 39 |
Duchaine, Yovel & Nakayama |
Severe acquired impairment of face detection and recognition with normal object recognition |
| 40 |
Dingle, Duchaine & Nakayama |
A new test for face perception |
| 41 |
Chiao, Kenser, Nakayama & Ambady |
Priming identity in biracial observers affects speed of visual search for different race faces |
| 42 |
Caldara, Smith, Han, Michel, McCotter, Chung & Schyns |
The face system is blind and inefficient to other-race faces |
| 43 |
Yoon & Hong |
Influence of facial expression on binocular rivalry between two faces |
| 44 |
Honma & Osada |
The effect of sharpness constancy on the recognition of facial expression |
| 45 |
Irwin, Jones, DeBruine, Williams & Mon-Williams |
'reading' dynamic facial expression in autistic spectrum disorder |
| 46 |
McGinty, DeBruine, Williams, Jones & Mon-Williams |
Interpreting facial expression following alcohol consumption |
| 47 |
Otsuka, Kanazawa, Yamaguchi, O'Toole & Abdi |
The effect of motion information on infants' recognition of unfamiliar face |
| 48 |
White, Williams, Jones, DeBruine & Mon-Williams |
Patterns of developmental advancement in 'reading' dynamic facial expression |
| 49 |
Lomber & Cornwell |
Dogs, but not cats, can readily recognize the face of their handler |
| 50 |
Oriet & Enns |
Prime-mask interactions in unconscious priming and conscious perception of emotional faces |
| Illusions |
51 |
Boi, Stara, Dasara, Penna & Pinna |
An illusion of misalignment |
| 52 |
Chuang & Rensink |
Seeing more than meets the eye - the ghost illusion |
| 53 |
Comerford, Thorn & Bodkin |
The chromatic Hermann grid illusion for stimuli equated in chroma |
| 54 |
Grossberg, Dasara & Pinna |
The problem of the perception of holes and figure-ground segregation in the watercolor illusion |
| 55 |
Gurnsey & Pagé |
The Pinna -Brelstaff Illusion is not optimal under self-motion conditions |
| 56 |
McAnany & Levine |
Magnocellular- and parvocellular-pathway processing in a novel visual illusion |
| 57 |
Miyahara, Klerer, Muna & Hwang |
The effect of chromaticities and shaft occlusion on the magnitude of the Mueller-Lyer illusion |
| 58 |
Pinna & Dasara |
The Windmill Illusion |
| 59 |
Kline, Holcombe & Eagleman |
The visual system does not take global snapshots of the visual field |
| 60 |
Dasara, Pinna & Wenderoth |
Undulation and twist illusions |
| 61 |
Hamburger & Spillmann |
New insights into 'Enigma' |
| Scene and Layout Perception |
62 |
Chan, Zavodni, Campos, Kok & Sun |
Spatial updating and spatial properties in scene recognition |
| 63 |
Huff, Garsoffky & Schwan |
Viewpoint independent scene recognition through a-priori instruction? |
| 64 |
Bian, Braunstein & Andersen |
The ground dominance effect depends both on the surface and its location in the visual field |
| 65 |
Sanocki |
Priming of scenic layout measured with an accuracy task |
| 66 |
Gottesman |
How far can you go? The ”extended” utility of scene layout priming |
| 67 |
Davenport |
Consistency effects in the perception of briefly viewed scenes |
| 68 |
Castelhano & Henderson |
The influence of color on perception of scene gist |
| 69 |
Torralba & Oliva |
Global statistical features and early scene interpretation |
| 70 |
Greene & Oliva |
Better to run than to hide: The time course of naturalistic scene decisions |
| 71 |
Maljkovic & Martini |
Effects of familiarity and repetition on memory for real-life scenes with emotional content |
| 72 |
Martini & Maljkovic |
Lack of interference between unfamiliar real-life scenes in RSVP streams |
| 73 |
DiMase, Chun, Scholl, Wolfe & Horowitz |
Learning scenes while tracking disks: The effect of MOT load on picture recognition |
| 74 |
Michod, Horowitz & Wolfe |
Picture memory demands attention |
| 75 |
Drew & Vogel |
Repeated masks are less effective |
| 76 |
Kikuchi, Sakai & Hirai |
The mechanism of 3D contour perception |
| 77 |
Smilek, van Leeuwen, Birmingham, Toufaniasl & Kingstone |
Exploring visual scenes: A cognitive ethology approach |
| 78 |
Hunter, Warlaumont & Edelman |
A behavioral handle on the phenomenology of scene perception |
| Visual Cortex:receptive fields |
79 |
Sundberg, Mitchell & Reynolds |
Contrast dependant center-surround interactions in macaque area V4 |
| 80 |
Tailby, Solomon, Dhruv, Majaj & Lennie |
Habituation reveals cardinal chromatic mechanisms in striate cortex of macaque |
| 81 |
Huang, Albright & Stoner |
Adaptive motion integration and antagonism in visual area MT |
| 82 |
Willmore, Prenger & Gallant |
Principles of neural shape coding in area V2 |
| 83 |
Rust, Simoncelli & Movshon |
Neurons in MT compute pattern direction by pooling excitatory and suppressive inputs |
| 84 |
Benucci, Frazor & Carandini |
Imaging the dynamics of orientation tuning in visual cortex |
| 85 |
Bair |
Modeling neuronal response dynamics and cross-correlation in V1: A comparison of architectures that use anti-phase feedforward inhibition and isotropic lateral inhibition |
| Object Recognition |
86 |
Vinberg & Grill-Spector |
Object and shape processing in the human lateral occipital complex |
| 87 |
Gajewski & Henderson |
Integrating information about real-world objects across eye movements |
| 88 |
Bar, Aminoff, Boshyan, Fenske, Gronauo & Kassam |
The contribution of context to visual object recognition |
| 89 |
Ghuman, Kassam, Boshyan & Bar |
Cortical interactions in top-down facilitation of visual object recognition through low spatial frequencies |
| 90 |
Nederhouser, Biederman, Davidoff, Yue, Kayaert & Vogels |
The representation of shape in individuals from a culture with limited contact with regular, simple artifacts |
| 91 |
Tong & Kim |
Transformation from position-specific to position-invariant coding of objects across the human visual pathway |
| 92 |
Kawasaki & Sheinberg |
Behavioral and physiological effects of backward masking and microstimulation in inferior temporal cortex of the monkey |
| Color channels and processes |
93 |
Bonnardel & Pitchford |
Structure of colour space derived from three different tasks |
| 94 |
Shevell & Cao |
Chromatic assimilation measured by temporal nulling: Interaction between the l and s pathways |
| 95 |
Mullen, Dumoulin, McMahon, Bryant, de Zubicaray & Hess |
A comparison of the BOLD fMRI response to achromatic, L/M opponent and S-cone opponent cardinal stimuli in human visual cortex: I. perceptually matched vs contrast matched stimuli |
| 96 |
Shapiro |
First-order color vision is slow; Second-order color vision is fast |
| 97 |
Bompas & O'Regan |
More evidence for sensorimotor adaptation in color perception |
| 98 |
Monnier, Shevell & Young |
Induction from a chromatic pattern that cannot be seen |
| Eye movements, perception, and action |
99 |
Gee, Ipata, Bisley & Goldberg |
Activity in monkey lateral intraparietal area reflects saccade direction, saccade latency, and target identification during free visual search |
| 100 |
Platt & McCoy |
Neural correlates of subjective spatial bias in macaque posterior cingulate cortex |
| 101 |
Jovancevic, Sullivan & Hayhoe |
Attentional capture for potential collisions gated by task |
| 102 |
Histed & Miller |
Sef microstimulation reorders spatial memories in a convergent manner |
| 103 |
Nezhad, Motamed & Tjan |
Perceive the slow but pursue the fast – eye movement during shape-from-motion (SfM) with ambiguous stimuli |
| 104 |
Irwin & Thomas |
Cognitive saccadic suppression: number comparison is suppressed during leftward saccades |
| Attentional blink |
105 |
Arend, Johnston & Shapiro |
Illusory motion attenuates the attentional blink |
| 106 |
Johnston, Shapiro, Roberts & Zhaman |
Working memory and the attentional blink |
| 107 |
Ghorashi, Smilek & Di Lollo |
Information about a spatial cue survives the attentional blink |
| 108 |
Crewther, Meadows & Crewther |
Decision, awareness and false alarms in the attentional blink - a psychophysiological study |
| 109 |
Loach, Tombu & Tsotsos |
Interactions between spatial and temporal attention: an attentional blink study |
| 110 |
Nieuwenstein |
Target detection triggers a slow attentional response in the attentional blink |
| 111 |
Dux & Coltheart |
The meaning of the mask matters: Evidence of conceptual interference in the attentional blink |
| 112 |
Kawahara, Gabari & Enns |
Testing the two-stage competition model of the attentional blink: Competition or a cost in distractor rejection? |
| 113 |
Richer, Marti, Paradis & Thibeault |
The attentional blink and automatic orienting |
| 114 |
Martin & Shapiro |
The role of T1 masking at short lags in the attentional blink |
| 115 |
Tsushima & Watanabe |
Subliminal task-irrelevant motion signals more severely disrupt RSVP task performance than supraliminal signals |
| 116 |
Wyble & Bowman |
The attentional blink reflects the time course of token binding, computational modeling and empirical data |
| Hand movements I |
117 |
Brouwer, Franz, Kerzel & Gegenfurtner |
Fixating for grasping |
| 118 |
Yamaguchi & Kaneko |
Eccentric head and eye positions affect proprioceptive pointing |
| 119 |
Fischer, Prinz & Lotz |
Obligatory attention to action goals |
| 120 |
Feloiu, Marotta, Black & Crawford |
Adaptation to reversing prisms: Pointing in patients with right-parietal damage |
| 121 |
Heider, Ahrens & Siegel |
Neural activity in monkey parietal area 7a during reaching and the effects of prism adaptation |
| 122 |
Lee, Bingham, Norman & Crabtree |
Calibration of shape perception used to guide reaches-to-grasp |
| 123 |
Mulroue, Mon-Williams & Williams |
Patterns of developmental advancement in visually-controlled goal directed action |
| 124 |
Mon-Williams & Bingham |
Task constraints alter prehension movements qualitatively and quantitatively |
| 125 |
Wu, Maloney & Dal Martello |
Movement planning in a rapid 'foraging' task: Maximization of expected gain in strategy selection? |
| 126 |
Tassinari, Landy & Hudson |
Combining priors and noisy visual cues in rapid pointing |
| 127 |
Trommershauser |
Sensory-motor choices among configurations with variable expected gain |
| 128 |
Obhi & Goodale |
Evidence for differential weighting of egocentric and allocentric cues in delayed and real-time actions |
| 129 |
Tani, Nakajima, Maruya & Sato |
The role of the visual feedback on the pointing behavior |
| 130 |
Ma-Wyatt & McKee |
The last moment for a change in pointing direction |
| Motion 1 |
131 |
Collier & Cobo-Lewis |
The effects of spatial-frequency and contrast ratio manipulations differ with dioptic and dichoptic viewing of Type 2 plaids |
| 132 |
Morvan & Wexler |
The timing of space constancy during smooth pursuit eye movements |
| 133 |
Rajimehr |
Anisotropic center-surround antagonism in visual motion perception |
| 134 |
Schlack, Krekelberg & Albright |
Speed history effects of visual stimuli |
| 135 |
Souman & Freeman |
Signal latencies in motion perception during sinusoidal smooth pursuit |
| 136 |
Tong, Aydin & Bedell |
Direction-of-motion discrimination is facilitated by visible motion smear |
| 137 |
Bedell, Lien, Tong, Cisarik & Patel |
Motion sensitivity and fixation variability along individual meridians |
| 138 |
Maruya & Sato |
A contribution of early motion systems on stream-bounce perception |
| 139 |
Shrivastava, Hayhoe, Pelz & Mruczek |
Influence of optic flow field restrictions and fog on perception of speed in a virtual driving environment |
| 140 |
Royden, Connors & Mahoney |
Thresholds for detection of a moving object by a moving observer |
| 141 |
Yeshurun |
Motion perception is differentially effected by the transient and sustained components of spatial attention |
| 142 |
Goutcher & Loffler |
Motion transparency in combined first and second order stimuli |
| 143 |
Greenwood & Edwards |
Speed differences increase the number of transparent motion signals that can be detected simultaneously |
| 144 |
Kanaya, Maruya & Sato |
The contribution of low-level motion systems in multiple object tracking |
| 145 |
MacKenzie & Wilcox |
Second-order motion alone does not convey ordinal depth information |
| 146 |
Posey & Watamaniuk |
Perception and discrimination of global flow speed reveals motion coding |
| 147 |
Cobo-Lewis, Collier, Khin & Carlow |
Perceived direction of drifting Type 2 plaids is biased toward higher-reliability component |
| 148 |
Nguyen-Tri & Faubert |
The effect of luminance texture on MAEs |
| 149 |
Curran & Benton |
The dynamic motion aftereffect is driven by local motion adaptation |
| 150 |
O'Kane & Mamassian |
Temporal dynamics of the motion aftereffect |
| 151 |
Sohn & Seiffert |
Effects of surface depth order on motion aftereffects |
| 152 |
Kamitani & Tong |
Decoding motion direction from activity in human visual cortex |
| 153 |
Lindholm & Tai |
Image generator resolution and motion quality |
| Performance and Attention |
154 |
McLin, Previc, Barnes, Dziuban & Hengst |
Lasers as a warning signal to communicate with aircraft |
| 155 |
Kuyk, Kosnik, Smith, Kee, Novar & Polhamus |
The effects of exposure to a 532 nm (green) laser on the visibility of flight symbology |
| 156 |
Stavrou, Wood & Battistutta |
Vision assessment of older drivers for relicensure |
| 157 |
Lo & Yeh |
Dissociating attention from required processing time |
| 158 |
Haun, Hansen, Kim & Essock |
Sequential effects and stimulus-response dependencies in an orientation identification task: characterization of the class 2 oblique effect |
| 159 |
Arman & Boynton |
Feature specificity of global-feature-based-attention |
| 160 |
Hauck, Gustas, Leary & Fine |
Both accuracy and response times vary depending on target location in a sustained attention task |
| 161 |
Lappin, Nyquist & Tadin |
Acquiring visual information from central and peripheral fields |
| 162 |
Poggel, Strasburger & MacKeben |
Relative motion in the periphery of the visual field is a powerful cue for visuo-spatial attention |
| 163 |
Gobell, Stanley & Carrasco |
Can transient attention offset the effects of sustained attention? |
| 164 |
Montagna, Yeshurun & Carrasco |
On the flexibility of covert attention and its effects on a texture segmentation task |
| 165 |
Pestilli & Carrasco |
Transient attention reduces the effect of adaptation |
| 166 |
Faludi, Avakov, Maloney & Marisa |
Covert transient attention affects motor response trajectories |
| 167 |
Paul, Tipper & Hayes |
Action affordance effects: Location and grasp |
| 168 |
Nishimura & Yokosawa |
Orthogonal Simon effect: A new interference effect with vertically arrayed stimuli and horizontally arrayed responses |
| 169 |
Montaser Kouhsari & Rajimehr |
Attentional modulation of orientation adaptation to resolvable and unresolvable patterns using brief orientation adaptation paradigm |
| 170 |
Hong, Papathomas & Vidnyánszky |
Can attention to auditory signals affect processing of simultaneous visual stimuli? |
| 171 |
Ciaramitaro & Boynton |
Visual-auditory spatial attention in human visual cortex |
| 172 |
Arnott & Goodale |
Distorting visual space with sound |
| Spatial Vision I |
173 |
Brooks, Tyrrell, Wood, Stephens & Stavrou |
Comparing estimated and actual visual acuity at high and low luminance |
| 174 |
Slack & Chubb |
The dependence of texture density judgments on texture element contrast |
| 175 |
Mareschal, Dakin & Bex |
Dynamics of collinear facilitation assessed using classification images |
| 176 |
Cameron |
Perceptual inhomogeneities in the upper visual field |
| 177 |
Levine & McAnany |
More ups and downs of visual processing |
| 178 |
Poder |
Effect of phase on the detection of spatial patterns |
| 179 |
Hess, Wang & Liu |
Accessibility of spatial channels |
| 180 |
Solomon & Morgan |
Contextual effects on orientation identification and contrast discrimination in the fovea |
| 181 |
Foley, Varadharajan, Koh & Farias |
Detection of gabor patterns |
| 182 |
Sukumar & Waugh |
Lateral spatial interactions for the detection of luminance-defined and contrast-defined blobs, at the fovea and in the periphery |
| 183 |
Oruc, Landy & Pelli |
Noise masking reveals channels for second-order letters |
| 184 |
Leaper, Sahraie, McGeorge & Carey |
Perceptual size distortion: Expansion of left hemispace |
| 185 |
Huang, Hess & Kingdom |
Labelled lines for phase? |
| 186 |
Kothari, Mahon & Carrasco |
Characterizing visual performance fields in children |
| 187 |
Lewis, Kingdon, Ellemberg & Maurer |
Sensitivity to tilt in first-order and second-order gratings is immature in 5-year-olds |
| 188 |
Malpeli, Kang, Reem & Kaczmarowski |
Scotopic contrast sensitivity: Cat versus human |
| 189 |
Aspell, Braddick, Atkinson, Wattam-Bell & Bridge |
Concentric and parallel textures differentially activate human visual cortex |
| 190 |
Payne, Sowden & Myers |
Measuring the activity of spatial frequency channels using fMRI-adaptation |
| 191 |
Menees & Bach |
Normal variability of reversal- and onset-VEPs and their amplitude measurement |
| 3D Space Perception |
192 |
Howard, Nguyen & Cheung |
Perception of the horizontal during roll rotation of self or scene |
| 193 |
Dyde, Jenkin & Harris |
Cues that determine the perceptual upright: Visual influences are dominated by high spatial frequencies |
| 194 |
Stefanucci, Proffitt & Clore |
Skating down a steeper slope: The effect of fear on geographical slant perception |
| 195 |
Riener, Witt, Stefanucci & Proffitt |
Seeing beyond the target: An effect of environmental context on distance perception |
| 196 |
Dilda, Creem-Regehr & Thompson |
Perceiving distances to targets on the floor and ceiling: A comparison of walking and matching measures |
| 197 |
Glennerster, Gilson & Tcheang |
The representation of visual space in an expanding room |
| 198 |
Schnall, Witt, Augustyn, Stefanucci, Proffitt & Clore |
Invasion of personal space influences perception of spatial layout |
| 199 |
Wu, He & Ooi |
The idiosyncrasies of foreshortening and what they reveal about space vision |
| 200 |
Wu & Klatzky |
Spatial updating of locations after posture changes in the vertical dimension |
| Target mislocalization |
201 |
Park, Shimojo & Schlag |
Distorting visual space without motion signal |
| 202 |
Arnold & Johnston |
Sub-threshold motion influences apparent position |
| 203 |
Brenner, Mamassian & Smeets |
If we saw it, it must have been where we were looking! |
| 204 |
Cantor & Schor |
The flash-pulfrich effect |
| 205 |
Lopez-Moliner & Linares |
Internal and external prediction in the fash-lag effect |
| 206 |
Yokoi & Watanabe |
Distortion of positional representation of visual objects by motion signals |
| 207 |
de Grave, Franz & Gegenfurtner |
The coding of combined pointing movements and saccades in the Brentano illusion |
| Contours / Form Perception |
208 |
Anderson, Habak, Wilkinson & Wilson |
Evaluating curvature aftereffects with radial frequency contours |
| 209 |
Habak, Wilkinson & Wilson |
Properties of shape interaction in temporal masking |
| 210 |
Wang & Felius |
The role of spatial phase in the detection of position-defined and orientation-defined linear and circular contour deformation |
| 211 |
Clifford & Weston |
Aftereffect of adaptation to glass patterns |
| 212 |
Kalar, Garrigan & Kellman |
Second-order contour discontinuities in segmentation and shape representation |
| 213 |
Li |
Effect of dichoptically presented reference on systematic shape distortion during pursuit eye movement |
| 214 |
Cohen & Singh |
Perceived orientation of complex shapes reflects graded part decomposition |
| 215 |
Eidels & Townsend |
Systems factorial technology analysis of Pomerantz's configural figures |
| 216 |
Niimi, Watanabe & Yokosawa |
Rapid successive presentation improves symmetry perception |
| 217 |
Peterson & Skow |
Intermediate level, medium-span, configurations can trigger past experience effects on figure assignment |
| 218 |
Rasche |
Shape recognition with propagation fields |
| 219 |
Strasburger |
Character recognition and Ricco's law |
| 220 |
El-Shamayleh, Kiorpes & Movshon |
Different aspects of form perception develop at diffierent rates |
| Conscious perception |
221 |
Haynes & Rees |
Predicting the orientation of invisible stimuli from activity in human primary visual cortex |
| 222 |
Schyns, Smith & Gosselin |
Brain correlates of conscious perceptions |
| 223 |
Bonneh, Sagi & Cooperman |
Learning to ignore: Practice can increase disappearance in motion induced blindness |
| 224 |
Hsieh, Caplovitz & Tse |
Neural correlates of conscious visibility found in ipsilateral retinotopic cortex |
| 225 |
Whitney |
Visual motion shifts perceived position without awareness of the motion |
| Spatial Vision |
226 |
Petrov, Carandini & McKee |
Surround masking comes after cross-orientation masking, and is only found in the periphery |
| 227 |
Tjan & Dang |
The spatial interaction zone of a shapeless noise flanker |
| 228 |
Zhaoping |
Modeling neural tuning to border ownership of figures through intracortical interactions in V2 |
| 229 |
Manahilov, Simpson & Calvert |
Classification images for second-order patterns |
| 230 |
Wang & Simoncelli |
Maximum differentiation competition: A methodology for comparing quantitative models of perceptual discriminability |
| 231 |
Durant & Clifford |
Dynamics of centre-surround interactions in orientation perception |
| Attentional Mechanisms |
232 |
Carrasco, Giordano & McElree |
Temporal dynamics of covert attention |
| 233 |
Ivanoff, Branning & Marois |
The neural hæmodynamics of a speed-accuracy tradeoff in decision making |
| 234 |
Tseng, Vidnyánszky, Papathomas & Sperling |
Attention-based long-lasting sensitization and suppression of colors |
| 235 |
Palmer, McKinley, Mazurek & Shadlen |
Effect of prior probability on choice and response time in a motion discrimination task |
| 236 |
Ghose & Walsh |
Temporal kernels of motion perception are sharpened by training and attention |
| 237 |
VanRullen, Reddy & Koch |
Attention-dependent discrete sampling of motion perception |
| 238 |
Reddy, Wilken, Quian-Quiroga, Koch & Fried |
Single neuron correlates of change blindness in the human medial temporal lobe |
| Lightness and Surfaces |
239 |
Gilchrist & Radonjic |
Lightness computation in the simplest images |
| 240 |
Radonjic, Gilchrist & Ramachandran |
Does target lightness depend on background luminance or background lightness? |
| 241 |
Spehar, Iglesias & Clifford |
Assimilation and contrast in complex configurations |
| 242 |
McCourt, Blakeslee & Pasieka |
Temporal properties of brightness induction |
| 243 |
Tarr, Di Luca & Zosh |
Deformation of perceived shape with multiple illumination sources |
| 244 |
Tse, Caplovitz & Hsieh |
Voluntary attention modulates the brightness of overlapping transparent surfaces |
| 245 |
Cant & Goodale |
An fMRI investigation of the perception of form, texture, and colour in human occipito-temporal cortical pathways |
| Adaptation |
246 |
Elliott, Webster & Georgeson |
Adaptation to blur: normalization or repulsion? |
| 247 |
Hsu, Yeh & Kramer |
The influence of different surface segregation cues on temporary blindness |
| 248 |
MacLeod & Beer |
Vision works by concatenating factors of change |
| 249 |
Smith & Rogers |
High intensity flash-probe measurements of visual adaptation |
| 250 |
Müller, Ernst & Leopold |
Simple stimulus metrics vs. Gestalt in high-level aftereffects |
| Binocular Stereopsis |
251 |
Harris & Drga |
Scene layout and binocular distance perception: Effects of angular separation |
| 252 |
Doi, Tanabe, Umeda & Fujita |
Drastic differences in binocular disparity tuning of V4 cells for random dots and solid figures: Quantitative analysis and mechanisms |
| 253 |
Read & Cumming |
Explaining depth perception in dynamic noise with an interocular delay |
| 254 |
Visco & Stevenson |
Time course of local adaptation in the pulfrich phenomenon |
| 255 |
Zhao & Farell |
The absolute phase effect in energy model |
| 256 |
Meyerson & Banks |
The visual system does not compensate for different image sizes in the two eyes that result from eccentric gaze |
| 257 |
Vreven |
Adaptation to interpolated dispairty |
| 258 |
Akai, Hoskinson, Fisher & Dill |
Depth and size perception in stereo displays |
| 259 |
Fukuda & Kaneko |
Vertical size disparity and perceived position measured by perceptual and action tasks |
| 260 |
Gillam, Pianta, Seizova-Cajic & Brooks |
Stereoscopic slant seen against monocular surrounds |
| 261 |
Patel & Bedell |
Non-horizontal disparities enhance sensitivity of the human stereovision system |
| 262 |
Sedgwick, Gillam & Shah |
Incomplete integration of local and global information in stereopsis |
| 263 |
Zhang & Schor |
Partial occlusion influences the binocular matching solution |
| Color vision 1 |
264 |
Solomon, Dhruv & Lennie |
Spatial organization of L- and M-cone inputs to neurons in the macaque lateral geniculate nucleus |
| 265 |
Dumoulin, Mullen, McMahon, Bryant, de Zubicaray & Hess |
A comparison of the BOLD fMRI response to achromatic, L/M opponent and S-cone opponent cardinal stimuli in human visual cortex: II. chromatic vs achromatic stimuli |
| 266 |
Kuriki |
Multiple-channel characteristics from chromatic notched-noise adaptation |
| 267 |
Svec, Elliot, Highsmith, Brunstetter & Crognale |
The effect of spectrally selective filters on perception |
| 268 |
Lewis & Zhaoping |
Cone tuning curves and natural color statistics |
| 269 |
Ozgen & Davies |
Effects of learning and language on colour categorical perception as measured by simultaneous presentation threshold estimates |
| 270 |
Kraft |
Implications of variability in color constancy across different methods and individuals |
| 271 |
Reeves, Amano & Foster |
Color Constancy: the role of judgement |
| 272 |
Uchikawa, Nakajima & Segawa |
Categorical color constancy for dichromats |
| 273 |
Ortega & Mel |
A probabilistic approach to color constancy using articulation, brightness, and gamut cues |
| 274 |
Ouyang & Kraft |
Simultaneous contrast and color constancy in authentic environments: impoverished vs. rich scenes |
| 275 |
Zemach & Teller |
Infants' spontaneous hue preferences are not due solely to variations in chromatic detection thresholds |
| 276 |
Pitts, Volbrecht, Troup, Nerger & Dakin |
Color appearance in the peripheral retina as a function of stimulus size and intensity under rod-bleach conditions |
| 277 |
Yoonessi & Kingdom |
Sensitivity to color and luminance transformations in real versus phase-scrambled natural scenes |
| 278 |
Cunningham & Tjan |
Spatial arrangement of irrelevant color in visual search |
| 279 |
Nishida, Watanabe & Kuriki |
Motion-induced colour segregation |
| 280 |
Webster & Kay |
Variation in focal color choices across languages of the world color survey |
| 281 |
Billock |
Missing links: Some examples from color vision on how binding theory may fill gaps in theoretical frameworks for perceptual phenomena |
| 282 |
Beer, Wortman, Horwitz & MacLeod |
Compensation of white for macular filtering |
| Visual disorders and blindsight |
283 |
Behrmann, Thomas, Kimchi & Minshew |
Visual perceptual organization in adults with autism |
| 284 |
Mendola & Conner |
Does eye dominance predict fMRI signals in retinotopic cortex? |
| 285 |
Ro, Harrison, Boyer & Greene |
Unconscious orientation and color processing without primary visual cortex |
| 286 |
Carey, Treventhan & Sahraie |
Revisiting manual localisation in the cortically blind field |
| 287 |
Trevethan, Sahraie & Weiskrantz |
When does a boy look like a gate? Form discrimination in blindsight? |
| 288 |
Spencer & O'Brien |
Imaging visual deficits in autistic spectrum disorder |
| 289 |
Landau, Aviezer, Robertson, Peterson, Soroker, Sacher, Bonneh & Bentin |
Implitict object recognition in visual integrative agnosia: Patient SE |
| 290 |
Wann, Field, Mon-Williams & Milner |
How would you catch a ball if you had visual form agnosia? |
| 291 |
Allen & Humphreys |
Orientation integration is intact in integrative agnosia |
| 292 |
Ho & Giaschi |
Low-level and high-level maximum motion displacement deficits in amblyopic children |
| 293 |
Sireteanu, Bäumer & Sârbu |
Temporal instability of amblyopic vision: Evidence for an involvement of the dorsal visual pathway |
| 294 |
Calvert, Bradnam, Manahilov, Hamilton, McCulloch, Mackay & Dutton |
Assessment of contrast sensitivity in infants and children with neurological impairment: A novel test using steady-state visual evoked potentials (ssVEPs) |
| 295 |
Conner & Mendola |
What does an amblyopic eye tell human visual cortex? |
| 296 |
de Wit, Schlooz, Hulstijn & van Lier |
Visual completion in children with pervasive developmental disorder: Effects of shape complexity |
| 297 |
Wittich, Overbury, Kapusta & Faubert |
Procedure- and stimulus-dependent differences in perceptual filling-in after macular hole surgery |
| 298 |
Palomares, Landau & Egeth |
Abnormal spatial integration in Williams Syndrome is distance-dependent |
| 299 |
Cheung, Schuchard, He, Tai, Legge & Hu |
Limited retinotopic reorganization in age-related macular degeneration |
| 300 |
Nyquist, Lusk, Lappin, Corn & Tadin |
Low vision differences between static and moving patterns in central and peripheral fields |
| 301 |
McCleery, Allman, Burner, Carver & Dobkins |
Psychophysical evidence for abnormal magnocellular processing in 6-month olds infants with autism in their family |
| 302 |
Zwick, Stuck, Edsall, Wood, Cheramie & Sankovich |
In Vivo characterization of laser induced photoreceptor damage and recovery in the high numerical aperture of the snake eye |
| Locomotion, steering and posture |
303 |
Zhong, Harrison & Warren |
The roles of spatial knowledge and visual landmarks in navigation |
| 304 |
Andre, Losier, Heiser, MeGehee & Campbell |
Investigating the effects of occlusion time on the visual guidance of blind-walking, veering, and distance perception |
| 305 |
Campos, Hsiao, Chan & Sun |
The influence of vision on the estimation of walked distance |
| 306 |
Mohler, Creem-Regehr & Thompson |
Speed of visual flow affects comfortable walking speed |
| 307 |
Falkenberg & Bex |
Does the location of visual field loss change mobility and fixation behaviour when walking an unfamiliar environment? |
| 308 |
Philbeck |
Rapid recalibration of locomotion during non-visual walking |
| 309 |
Willemsen, Creem-Regehr, Colton & Thompson |
The effect of HMD mass and inertia on visually directed walking in virtual environments |
| 310 |
Owens & Warren |
Intercepting moving targets on foot: Can people learn to anticipate target motion? |
| 311 |
Bruggeman & Warren |
Integrating target interception and obstacle avoidance |
| 312 |
Cohen & Warren |
Switching behavior in moving obstacle avoidance |
| 313 |
Li, Sweet & Stone |
Heading off the beaten path |
| 314 |
Macuga, Beall, Loomis, Smith & Kelly |
In steering without visual feedback, subjects can properly initiate the return phase of a “lane change” maneuver |
| 315 |
Elder, Grossberg & Mingolla |
A neural model of visually-guided steering and obstacle avoidance |
| 316 |
Enriquez, Ni, Bower & Andersen |
Covert orienting of attention and the perception of heading |
| 317 |
Diaz & Fajen |
Visual control of braking behind a moving lead vehicle |
| 318 |
Fajen |
Rapid recalibration in visually guided braking |
| 319 |
Seno & Sato |
The direction of vection is controlled by perceived motion |
| 320 |
Faubert, Allard & Hanssens |
Effect of visual sway on postural balance in a full immersive environment |
| 321 |
Tsuruhara & Kaneko |
Effects of motion and tilt of large-visual-stimulus on perception and postural control |
| 322 |
Wilkie & Wann |
Gaze polling and fixation shifting of cyclists negotiating a slalom |
| 323 |
Witt, Proffitt & Epstein |
Seeing into the Future: An interaction between perception and action |
| Motion in Depth 1 |
324 |
Amiri & Schrater |
Effects of binocular disparity and optic flow noise on visual cue integration for motion-in-depth |
| 325 |
Bocheva & Braunstein |
Effects of object and background spatial frequency on the perceived shape of a moving object |
| 326 |
Mao |
Quadri-stable percepts for a rotating non-transparent object |
| 327 |
Shirai, Kanazawa & Yamaguchi |
Early development of anisotropic sensitivities for expansion/contraction detection |
| 328 |
Wurfel, Padilla & Grzywacz |
Metric estimation of visual-deformation motions |
| 329 |
Imura, Yamaguchi, Tomonaga & Yagi |
Perception of motion trajectory from the moving cast shadow in human infants |
| 330 |
DeLucia |
Effective information for TTC judgments varies during an approach event |
| 331 |
Mitsudo & Ono |
Object velocity relative to the head and depth order from object-produced motion parallax |
| 332 |
Schaffer & Durgin |
Visual-vestibular dissociation: Differential sensitivity to acceleration and velocity |
| 333 |
Welchman, Maier & Buelthoff |
The role of binocular cues in scaling the retinal velocities of objects moving in space |
| 334 |
Durgin |
Adaptive sensory coding: Enhanced visual velocity discrimination during self-motion |
| 335 |
Dyre, Schaudt & Lew |
Contrast gradients increase apparent egospeed while moving through simulated fog |
| 336 |
Gray, Castaneda, Sieffert & Regan |
Comparing the relative accuracy of perception and action in ball catching |
| 337 |
Battaglia, Schrater & Kersten |
A Bayesian theory for intercepting objects moving in 3D |
| 338 |
Lages |
Bayesian models of 3-D motion perception |
| Perceptual Organization 1 |
339 |
Cantlon & Brannon |
Relative salience of number, shape, color, and surface area in rhesus monkeys |
| 340 |
Chan & Hayward |
When is preattentive grouping sensitive to contrast polarity? |
| 341 |
Fantoni, Hilger, Gerbino & Kellman |
Surface interpolation and 3D relatability |
| 342 |
Kim & Peterson |
Correct grouping of contours is required for symmetry to operate as a configural cue |
| 343 |
Vandenbroucke, Scholte, Kemner & Lamme |
Activity in early visual areas reflects perceived surface layout in scene segmentation |
| 344 |
Ren, Fowlkes & Malik |
Familiar configuration enables figure/ground assignment in natural scenes |
| 345 |
Scheessele, Guthrie & Gottschalk |
Role of non-targets in detection of a target in visual search |
| 346 |
Wilson, Collins & Bingham |
Human movement coordination implicates relative direction as the information for relative phase |
| 347 |
van den Berg, Spanos & Kubovy |
The effect of synaesthetically induced colors on perceptual organization |
| 348 |
Tse & Gerhardstein |
A higher-order mechanism beyond good continuation in contour integration |
| 349 |
Slesar & Mack |
Perversible Figures: An Ironic Process in Perception |
| 350 |
Portillo & Pomerantz |
Evaluating grouping via emergent features: A systematic approach |
| 351 |
Strother & Kubovy |
The perceptual organization of curvilinear contours in structurally ambiguous dot patterns |
| 352 |
Cheries, Feigenson, Scholl & Carey |
Cues to object persistence in infancy: Tracking objects through occlusion vs. implosion |
| 353 |
Meyers, Ostrovsky & Sinha |
Visual de-fragmentation via high spatial frequencies |
| Hand movements II |
354 |
Gonzalez, Ganel & Goodale |
Perceptual illusions affect visually-guided actions with the non-dominant but not with the dominant hand |
| 355 |
Post & Coker |
Inverted vision-action dissociation with induced motion |
| 356 |
Franz |
Metacontrast masking: Effects of barely visible stimuli on pointing movements |
| 357 |
Pappas & Mack |
Does inattentional blindness potentiate action? |
| 358 |
Klatzky, Wu, Shelton & Stetten |
Efficacy of image-guided action is controlled by perception |
| 359 |
Pardhan & Gonzalez-Alvarez |
Disruption of binocular cues affects reaching and grasping to a greater extent than their absence |
| 360 |
Li & Matin |
The proximal/distal model explains hand-to-body distance-dependent accuracy of visually-guided manual behavior |
| 361 |
Singhal, Chinellato, Culham & Goodale |
Dual-task interference is greater in memory-guided grasping than in visually guided grasping |
| 362 |
Winkler, Wright & Chubb |
Dissociating the functions of visual pathways using equisalient stimuli |
| 363 |
Gomi, Abekawa & Nishida |
Implicit sensorimotor control: Rapid motor responses of arm and eye share the visual motion encoding |
| 364 |
Henderson, Williams & Mon-Williams |
The visual control of goal directed action in developmental co-ordination disorder |
| Brain stimulation, activity & perception |
365 |
Ruff, Blankenburg, Bjoertomt, Bestmann, Haynes, Rees, Josephs, Deichmann & Driver |
Occipital activations and deactivations induced by stimulation of the right human frontal eye field |
| 366 |
Fine, Freda, Greenwald, Horsager, Pishoy, Richard, Valerie, James, Robert & Mark |
The perceptual effects of retinal electrical stimulation |
| 367 |
Pezaris & Reid |
Microstimulation in LGN produces focal visual percepts: Proof of concept for a visual prosthesis |
| 368 |
Jolij & Lamme |
Tms induced affective blindsight reverts to affective blindness when stimulus visibility is increased |
| 369 |
Sutter |
Visually modulated endogenous activity: A component of active visual processing |
| 370 |
Schneider & Kastner |
The topography of the human lateral geniculate nucleus and superior colliculus as revealed by superresolved fMRI |
| Natural Images |
371 |
Mante, Frazor, Bonin, Geisler & Carandini |
Independence of gain control mechanisms in early visual system matches the statistics of natural images |
| 372 |
Triesch |
Learning efficient codes for natural images by combining intrinsic and synaptic plasticity |
| 373 |
Ballard & Rothkopf |
Learning visual representations with projection pursuit |
| 374 |
Rucci & Casile |
Fixational instability and natural scene representation |
| 375 |
Sharan, Li & Adelson |
Image statistics and reflectance estimation |
| 376 |
Wichmann, Rosas & Gegenfurtner |
Rapid animal detection in natural scenes: Critical features are local |
| Face Recognition |
377 |
Jacques & Rossion |
Temporal dissociation of spatial attention and competition effects between face representations |
| 378 |
Gauthier & Cheung |
How holistic processing is affected by working memory load |
| 379 |
Bülthoff & Newell |
Accuracy in face recognition: Better performance for face identification with changes in identity and caricature but not with changes in sex |
| 380 |
O'Toole, Jiang & Blanz |
Three-dimensional shape and surface reflectance contributions to opponent-based face identity adaptation |
| 381 |
Rutherford & Chattha |
The use of afterimages in the study of categorization of facial expressions |
| Perception and action |
382 |
Quinlan, Goodale & Culham |
Don't bite the hand that feeds you: A comparison of mouth and hand kinematics |
| 383 |
Mennie, Hayhoe, Stupak & Sullivan |
Sources of information for catching balls |
| 384 |
Song & Nakayama |
Selecting and pointing: Consecutive serial processing? |
| 385 |
Rogers & Spencer |
Heading toward distant targets: Optic flow and the recalibration of visual direction |
| 386 |
Thompson, Mohler & Creem-Regehr |
Does perceptual-motor recalibration of locomotion depend on perceived self motion or the magnitude of optical flow? |
| 387 |
DeAngelis, Gu & Angelaki |
MSTD population responses account for the eccentricity dependence of heading discrimination thresholds |
| Emotional and Social Influences on Attention |
388 |
Reynolds, Frischen, Gerritsen, Smilek & Eastwood |
Emotion in visual search: The selection of affective faces for awareness |
| 389 |
Tuller & Pinto |
Effects of anxiety on attention and visual memory |
| 390 |
Shimojo, Moradi & Koch |
Differential adaptation to face identity and emotional expression in the near absence of attention |
| 391 |
Rutherford, Goolsby, Raymond & Klein |
Spatial attentional cuing effects on emotional evaluation of faces |
| 392 |
Westoby & Raymond |
How persistent is attentional modulation of affective evaluation? |
| 393 |
Silverman, Lam, Safier, Delfiner, Stern & Silbersweig |
Emotional valence and the attentional blink: The impact of meaning on detection |
| 394 |
Deaner, Shepherd & Platt |
Social context influences gaze-following and neuronal activity in macaque area LIP |
| 395 |
Kim, Palomares & Egeth |
The interaction of body and gaze cues in directing attention |
| 396 |
Takahama, Kumada & Saiki |
Perception of other's action influences performance in Simon task |
| 397 |
Bach & Tipper |
Action simulation influences personality judgments |
| 398 |
Dressel & Atchley |
Conversation limits attention: The impact of conversation complexity |
| 3D Cue integration |
399 |
Kies & Chubb |
Irrelevant boundaries disrupt the short-term storage of visual information |
| 400 |
Backus, Hillis, Frumkin & Saunders |
Early temporal dynamics of cue combination for slant from stereo and texture |
| 401 |
van Mierlo, Brenner & Smeets |
Cue combination: Compulsion and the effects of asynchrony |
| 402 |
Hu, Knill & Brown |
Modeling dynamic re-weighting in visual cue integration |
| 403 |
Girshick & Banks |
Combining slant information from disparity and texture: Is fusion mandatory? |
| 404 |
Caudek & Domini |
Adaptation to the relation between visual cues affects perception of 3D shape |
| 405 |
Bingham, Mon-Williams, Jarrahi & Vinner |
Cue use under full cue conditions cannot be inferred from use under controlled conditions |
| 406 |
Kimura |
The effects of color segregation on the recovery of 3-D structure from motion |
| 407 |
Zhang, Schiller, Weiner & Slocum |
Depth from shading and disparity in humans and monkeys |
| Attention, Learning, & Memory |
408 |
Sussman & Jiang |
Short and long term learning in visual search: An unexpected interference |
| 409 |
Frischen & Tipper |
Long-term gaze cueing effects: Evidence for retrieval of prior attentional states from memory |
| 410 |
Becker & Sims |
Scene-specific memory guides the allocation of attention in natural scenes |
| 411 |
Holm & Mäntylä |
Eye movements in episodic memory |
| 412 |
Kunar, Michod & Wolfe |
When we use the context in contextual cueing: Evidence from multiple target locations |
| 413 |
Terao, Ogawa & Yagi |
The repetition of object identities modulates attentional guidance in visual search |
| 414 |
Neider & Zelinsky |
Effects of scene-based contextual guidance on search |
| 415 |
King, Shim & Jiang |
Implicit and explicit memory in scene based contextual cueing |
| 416 |
Peterson, Beck, Boot, Vomela & Kramer |
Little is remembered about rejected distractors in visual search |
| 417 |
Neth, Gray & Myers |
Memory models of visual search – searching in-the-head vs. in-the-world? |
| 418 |
Skow & Peterson |
Competing attention vectors van produce the appearance of memory-free visual search |
| 419 |
Yotsumoto, Kahana & Sekuler |
Vision leaves its fingerprints on memory: Recognition and identification memory for compound gratings |
| 420 |
Morgan & Tipper |
Is long-term inhibition of return caused by perceptual mismatch processes? |
| 421 |
Junge, Turk-Browne & Scholl |
Visual statistical learning through intervening noise |
| 422 |
Varakin & Levin |
Interactions between long-term visual working memory and attention |
| 423 |
Rauschenberger & Chu |
The effects of familiarity on encoding efficiency in visual search |
| 424 |
Ono & Kawahara |
Brief stimuli that evoke false memories seem to last longer |
| 425 |
Hyun & Luck |
Visual working memory as the substrate for mental rotation |
| 426 |
Johnson, Hollingworth & Luck |
The role of attention in binding features in visual working memory |
| 427 |
Xing & Bailey |
Attention and memory in air traffic control tasks |
| Visual neurons: properties |
428 |
Frazor, Mante, Bonin & Carandini |
Dynamics of spatial frequency tuning in lateral geniculate nucleus |
| 429 |
MacEvoy, Tucker & Fitzpatrick |
Characterizing V1 population responses to superimposed gratings |
| 430 |
Hood, Ghadiali, Zhang, Lee & Zhang |
Response-contrast functions for multifocal visual evoked potentials (mfVEP): A test of a model relating V1 activity to mfVEP activity |
| 431 |
Zhang, Zheng, Watanabe, Bi, Smith & Chino |
Delayed maturation of receptive-field center and surround in macaque V2 neurons |
| 432 |
Lyon, Nassi & Callaway |
Disynaptic connections from the superior colliculus to cortical area MT revealed through transynaptic labeling with rabies virus |
| 433 |
Schmeisser, Vann & Williams |
Nonlinear dynamical characterization of magnocellular neural population response variability |
| 434 |
Meigen & Krämer |
Multifocal VEP recordings can be used to identify the onset of cortical activity after visual stimulation for different parts of the visual field |
| Eye Movements - Cognitive |
435 |
Fogt & Bornhorst |
The influence of retinal smear on discrimination of single and surrounded moving letters |
| 436 |
Hernandez, Levitan, Schor & Banks |
Hand pointing is accurate following adaptation of saccadic gain |
| 437 |
Hsieh & Irwin |
Center blocks the square: Eye movements to absent objects are under cognitive control |
| 438 |
Kenner & Oliva |
Rapid goal-directed exploration of a scene: The choice between a direct and a pragmatic scan path |
| 439 |
Levitan, MacNeilage, Banks & Schor |
Do pursuit eye movements improve discrimination of object speed? |
| 440 |
Mulligan, Stevenson & Cormack |
The effect of plaid orientation on pursuit of partially-predictable motion |
| 441 |
Pelz, Rothkopf & Broskey |
Version and vergence eye movements in mobile observers |
| 442 |
Raghunandan, Frazier, Poonja, Roorda & Stevenson |
The effect of retinal jitter on referenced and un-referenced motion discrimination thresholds |
| 443 |
Sacks & Hollingworth |
Attending to original object location facilitates visual memory retrieval |
| 444 |
Satgunam, Chitkara & Fogt |
Ocular tracking of transiently occluded targets |
| 445 |
Shiu & Edelman |
Do complex motor sets have the same effect on express saccades as simple ones? |
| 446 |
Simion & Shimojo |
Orienting contributes to preference even in the absence of visual stimuli |
| 447 |
Watanabe & Tachi |
Visual persistence of saccade-induced image smear |
| 448 |
Pearson & Henderson |
Is gaze selection diagnostically tuned for spatial frequency during face recognition? |
| 449 |
Beutter, Toscano & Stone |
Top-down and bottom-up influences on saccades in a visual search task |
| 450 |
Fallah & Reynolds |
Contrast dependence of smooth eye movements using superimposed transparent surfaces |
| 451 |
Fine, Yurgenson & Moore |
Poor saccade control in a simple search task |
| 452 |
Hall-Haro, Frank & Johnson |
Infants' motion sensitivity predicts smooth pursuit performance but fails to predict perceptual completion |
| Contrast |
453 |
Adams, White, Drover, Earle & Courage |
A new psychophysical test for the rapid measurement of spatial contrast sensitivity in infants and young children |
| 454 |
Laurinen, Olzak & Saarela |
Summation processes in contrast-contrast |
| 455 |
Katkov, Gan, Tsodyks & Sagi |
Singularities in the inverse modeling of contrast discrimination and ways to avoid them |
| 456 |
Makous, Fiser & Bex |
Spatial but no spectral limits on contrast conservation |
| 457 |
Kontsevich & Tyler |
Neural circuitry revealed by near-threshold transducer nonlinearities |
| 458 |
Lesmes, Jeon, Lu & Dosher |
Bayesian adaptive estimation of threshold versus external noise contrast functions |
| 459 |
Cass, Spehar, Alais & Arrighi |
Spatial and temporal determinants of contrast facilitation and suppression |
| 460 |
Heckman, Cardinal, Harley, Bouvier, Carr & Engel |
Characterizing contrast response functions measured with rapid event-related fMRI |
| 461 |
Kang & Malpeli |
A comparison of behavioral contrast sensitivity with the constrast sensitivities of X and Y geniculate cells in the awake cat |
| 462 |
Smith, McLin, Kee, Novar & Garcia |
Laser induced fluorescence in the human lens |
| Contour and shape |
463 |
Kingdom & Prins |
Different mechanisms encode the shapes of contours and contour-textures |
| 464 |
Legault, Allard & Faubert |
Detecting curvature in first and second-order periodic line stimuli |
| 465 |
Poirier & Wilson |
Neural curvature mechanisms for shape perception |
| 466 |
Prins & Kingdom |
The role of local position in the detection of contour curvature |
| 467 |
Kennedy, Orbach & Loffler |
Changes in orientation and position do not affect angle discrimination: Shape does |
| 468 |
Garrigan & Kellman |
Contour shape effects on search performance: evidence for constant curvature coding |
| 469 |
Lovell |
Manipulating contour smoothness: Evidence that the association-field model underlies contour integration in the periphery |
| 470 |
Singh & Fulvio |
Testing the limits of good continuation: Does human vision extrapolate rate of change of curvature? |
| 471 |
Rainville, Yourganov & Wilson |
Closed-contour shapes encoded through deviations from circularity in lateral-occipital complex (LOC): An fMRI study |
| 472 |
Skoczenski & Gramzow |
Contour integration and hyperacuity in children with dyslexia |
| 473 |
Baker, Adler, Tse & Gerhardstein |
Can 6-month-old infants integrate individual elements to discriminate contours? |
| Spatial vision II |
474 |
Victor, Chubb & Conte |
A theoretical framework for texture parameterization |
| 475 |
Sezikeye & Gurnsey |
Modelling texture discrimination asymmetries using quadratic forms of random variables |
| 476 |
Olzak, Gabree & Laurinen |
Modeling lateral interaction in fine spatial discriminations: The plot thickens |
| 477 |
Morgenstern & Elder |
Noise does not shrink the summation region for grating detection |
| 478 |
Klein & Tyler |
Paradoxical, quasi-ideal, spatial summation in the modelfest data |
| 479 |
Hansen, Essock & Haun |
Psychophysical inferences about the interactions within and between sub-populations of striate neurons |
| 480 |
Gosselin, Chauvin, Worsley, Schyns & Arguin |
A statistics toolbox for classification images |
| 481 |
Nagai, Bennett & Sekuler |
Spatiotemporal templates for detecting 1st- and 2nd-order orientation- and luminance-defined targets |
| 482 |
Taylor, Bennett & Sekuler |
Noise detection: Summation of high spatial frequency information |
| 483 |
Allard, Créach & Faubert |
Different internal noise but same calculation efficiency for processing luminance-modulated (LM) and contrast-modulated (CM) stimuli |
| 484 |
Ahumada, Beard & Jones |
Modeling the detection of blurred visual targets in non-homogeneous backgrounds |
| 485 |
Polat & Sagi |
Modulation of the decision criterion by collinear lateral facilitation |
| 486 |
Yehezkel, Belkin, Sagi & Polat |
Adaptation to astigmatic lens: Effects on lateral interactions |
| 487 |
Bennett, Rousselet & Sekuler |
Symmetry perception: a high-density ERP approach |
| 488 |
Corballis, Parks, Holder & Shapiro |
Identification of luminance and contrast modulation signatures in the steady-state visual evoked potential |
| Motion: cortical mechanisms |
489 |
Ashida & Smith |
Retinotopic mapping of motion stimuli in human visual cortex |
| 490 |
Atkinson, Birtles, Wattam-Bell & Braddick |
Global form and global motion: Which develops first in infancy? VERP evidence |
| 491 |
Winawer, Witthoft, Huk & Boroditsky |
Common mechanisms for processing of perceived, inferred, and imagined visual motion |
| 492 |
Saygin & Sereno |
Retinotopy and its modulation by attention in higher cortical areas studied with structured motion stimuli |
| 493 |
Tadin, Lappin & Blake |
Relative timing of center and surround signals in motion revealed by temporal reverse correlation |
| 494 |
Jazayeri & Movshon |
Visual motion processing in a direction discrimination task |
| 495 |
Zaksas, LaMendola & Pasternak |
Direction selective activity in prefrontal cortex during a working memory for motion task |
| Perceptual organization |
496 |
Anderson |
Non-Bayesian contour synthesis |
| 497 |
Chen & Han |
Local and global features in glass patterns are processed in different brain areas |
| 498 |
Herzog & Ogmen |
Perceptual grouping induces real-time remapping of retinotopy |
| 499 |
Palmer & Nelson |
The hole paradox: Perceiving and remembering the shapes of intrinsic vs. accidental holes |
| 500 |
von der Heydt & Pierson |
Dissociation of color and figure-ground effects in the watercolor illusion |
| 501 |
Zhou & Mel |
Combining cues for boundary detection using the "mixture of specialists" model |
| 502 |
Otto & Herzog |
Transporting features |
| Attentional Cuing and Capture |
503 |
Amster & Nagy |
Attentional capture by color and onset singletons in search tasks |
| 504 |
von Muhlenen, Rempel & Enns |
Attentional capture by unique temporal change |
| 505 |
Lovejoy, Chukoskie & Krauzlis |
Attention capture alters motion discrimination |
| 506 |
Gibson & Bryant |
What kind of attention is controlled by irrelevant symbolic cues? |
| 507 |
Chu & Edelman |
The modulation of attentional capture by behavioral relevance |
| 508 |
Ambinder & Simons |
The necessity of a spatial cue for the capture of attention by abrupt onsets |
| 509 |
Sahraie, Milders, Murray & Niedeggen |
Active suppression of salient visual distractors for uni-modal and cross-modal cues in dual RSVP tasks |
| 510 |
Bemis, Franconeri & Alvarez |
It takes attention to capture attention |
| 511 |
Jiang, Fang, Huang & He |
Invisible interesting pictures can attract spatial attention |
| 512 |
Kaldy, Blaser, Kibbe & Pomplun |
What drives visual salience in young infants? |
| 513 |
Kristjansson, Ruff & Driver |
Commonalities and differences between attentional cueing and iconic memory |
| 514 |
Shimozaki, Schoonveld & Eckstein |
An ideal observer approach to unifying set size and cueing effects for perceptual and saccadic decisions |
| 515 |
Matsukura & Vecera |
“Your first organization influences your second”: Does attention stick to location, color, or both? Evidence from a priming paradigm |
| 3D visual processing |
516 |
Fermuller & Ji |
On the anisotropy in the perception of stereoscopic slant |
| 517 |
Vishwanath, Girshick & Banks |
Local surface slant determines perceived shape in pictures |
| 518 |
Norman & Wiesemann |
Aging and the perception of surface orientation |
| 519 |
Farell |
The perception of symmetry in depth |
| 520 |
Granrud, Haynes, Juhl, Miller & Sandbach |
Perceived size of stoplights: Further investigations into a failure of size constancy |
| 521 |
Li & Pizlo |
Monocular and binocular perception of 3D shape: The role of a priori constraints |
| 522 |
Phillips, Casella & Gaudino |
What can drawing tell us about our mental representation of shape? |
| 523 |
Schofield, Hesse & Georgeson |
Texture amplitude is a cue to perception of shape from shading |
| 524 |
van Doorn, de Ridder & Koenderink |
Pictorial relief in equiluminant images |
| 525 |
Fleming & Bülthoff |
Orientation fields in the perception of 3D shape |
| 526 |
Weiderbacher, Pierre, Fleming & Neumann |
Perception of mirrored objects |
| 527 |
Interrante, Anderson & Ries |
Lack of 'presence' may be a factor in the underestimation of egocentric distances in immersive virtual environments |
| 528 |
Shuwairi, Albert & Johnson |
Discrimination of possible and impossible objects in early infancy |
| Faces: Cognition and Brain |
529 |
Wong, Palmeri, Gauthier & Tanaka |
The time-course of basic- and subordinate-level categorization of faces and objects |
| 530 |
Cheung & Gauthier |
How holistic processing is affected by perceptual load |
| 531 |
Curby & Gauthier |
Dissociating visual short-term memory and perceptual capacity for faces and objects |
| 532 |
Schiltz & Rossion |
Faces are processed holistically in the right middle fusiform gyrus |
| 533 |
Bukach, Bub, Gauthier & Tarr |
Spatially restricted perceptual expertise for faces in a case of prosopagnosia |
| 534 |
Hayward, Rhodes, Winkler & Schwaninger |
Own-race face effects in processing of configural and component information by Chinese observers |
| 535 |
Singer & Sheinberg |
The temporal extent of holistic processing |
| 536 |
Kim, Kim, Moon & Jeon |
A single recognition system for faces and objects in expertise-based experiments using synthetic stimuli |
| 537 |
Harley, Pope, Villablanca & Engel |
Neural bases of perceptual expertise in radiologists |
| 538 |
Harris & Nakayama |
Face-selective "double-pulse" adaptation of the M170 response |
| 539 |
Michel, Caldara, Han, Chung & Rossion |
Is holistic perception of faces specific to our own-race ? |
| 540 |
Goffaux & Rossion |
Faces are “spatial”- Holistic perception of faces is subtended by low spatial frequencies |
| 541 |
Kung, Ellis & Tarr |
An "other-race" effect in perceptual expertise: The interaction between task and stimulus familiarity in bird experts |
| 542 |
Ellis, Kung & Tarr |
Interaction of visual and auditory expertise in birders |
| 543 |
Carlson, Kim, Grol, Kim & Verstraten |
Timecourse and anatomy of recognizing a familiar face |
| 544 |
Suh & Grill-Spector |
The influence of holistic information on face detection |
| Inattentional blindness |
545 |
Fougnie, Todd & Marois |
Visual short-term memory load induces inattentional blindness |
| 546 |
Cartwright-Finch & Lavie |
Perceptual load induces inattentional blindness |
| 547 |
Apfelbaum, Apfelbaum, Woods & Peli |
The effect of edge filtering on inattentional blindness |
| 548 |
Carmi & Itti |
Why do we fail to perceive jump-cuts in motion pictures? |
| 549 |
Boot, Becic, Kramer, Kubose & Wiegmann |
Detecting transient changes in dynamic displays: The more you look, the less you see |
| 550 |
Jewell |
Did you see that? Unexpected events and salience |
| 551 |
Shen, King & Jiang |
Failed change detection produces volatile short-term memory |
| 552 |
Levin |
Change detection in normal, jumbled and inverted scenes |
| 553 |
Laloyaux & Cleeremans |
Implicit change detection: The fat lady hasn't sung yet |
| 554 |
Angelone, Beck & Levin |
Incidental change detection and working memory load in a dual-task paradigm |
| 555 |
van Montfort, de Greef & Bouwhuis |
Method to detect a gist change |
| 556 |
Massin & Mack |
Threat images attentuate change blindness |
| 557 |
Orbach, Henderson, Dutton, McCulloch, Gilchrist & Conway |
Distinguishing deficits in change detection from deficits in spatial attention in older adults |
| Lightness & surfaces (P) |
558 |
Koenderink, van Doorn, Kappers, Pont & Todd |
The perception of light fields in empty space |
| 559 |
Issolio & Colombo |
Humans perform brightness task under glare condition using ratio matching |
| 560 |
Kurki, Hyvärinen & Laurinen |
Exploring the spatiotemporal dynamics of brightness perception by reverse correlation |
| 561 |
Rudd, Zemach & Heredia |
Edge integration and anchoring in lightness perception: Further evidence against the highest luminance rule |
| 562 |
Livingstone & Howe |
White's effect: removing the junctions but preserving the strength of the illusion |
| 563 |
Son & Li |
Effect of late visual information processing on simultaneous lightness contrast |
| 564 |
Soranzo & Fantoni |
Semi-transparent layers enhance the simultaneous lightness contrast |
| 565 |
Langer & Gipsman |
Elongations near intensity maxima: a cue for shading? |
| 566 |
Fulvio, Singh & Maloney |
Combining achromatic and chromatic cues to transparency |
| 567 |
Gori |
Imperfect scission in achromatic transparency |
| 568 |
Ho, Landy & Maloney |
Change in illuminant direction alters perceived surface roughness |
| 569 |
Motoyoshi, Nishida & Adelson |
Image statistics as a determinant of reflectance perception |
| Modal and amodal completion |
570 |
Dillenburger & Wehrhahn |
Backward masking of illusory contours or their inducers depends on timing |
| 571 |
Hilger & Kellman |
Tolerance for misalignment in contour interpolation: retinal or relational? |
| 572 |
Hochstein, Barlasov & Weinstein |
Illusory shape pop out: Effects of perceptual learning |
| 573 |
Werner, Pinna & Spillmann |
Modes of darkness appearance: The blacker-than-black effect |
| 574 |
Barraza & Chen |
Amodal completion improves perception of illusory contours defined by motion |
| 575 |
Fang & Grossberg |
How are complex stereograms that define partially occluded surfaces amodally completed in depth? |
| 576 |
Liu & Schor |
The effect of occlusion on amodal completion and surface slant perception |
| Eye movements: physiology and mechanisms |
577 |
Sylvester, Haynes & Rees |
Saccadic modulation of activity in human LGN and V1 |
| 578 |
Hafed & Krauzlis |
Activity of superior colliculus neurons during parafoveal pursuit |
| 579 |
Liston & Krauzlis |
Interaction between visual and prior information on superior colliculus neurons |
| 580 |
Cassanello & Ferrera |
Vector subtraction and eye position gainfields in macaque frontal eye field |
| 581 |
McPeek |
Incomplete suppression of distractor-related activity in frontal eye field results in curved saccades |
| 582 |
Bendiksby & Platt |
Motivational scaling of visual responses in macaque area lip |
| 583 |
Pasupathy & Miller |
Saccade direction information appears earlier in the caudate nucleus than the frontal eye fields and prefrontal cortex during conditional visuomotor learning |
| 584 |
Wilmer & Nakayama |
Two components of oculomotor pursuit isolated by covariance based methods |
| 585 |
White, Gegenfurtner & Kerzel |
Effects of structured backgrounds on the latency of saccadic eye movements |
| 586 |
Moon, Cain, Polli, Barton & Manoach |
Signal timing and hemispheric localization in the human saccadic system: Preparatory processes and the sensorimotor transformation for antisaccades |
| 587 |
Kojo, Berg, Simola & Häkkinen |
The structure of fixational eye movements during turning gaze path |
| 588 |
Kodaka, Sheliga, FitzGibbon & Miles |
Radial-flow vergence eye movements depend critically on the local fourier components of the motion stimulus |
| 589 |
Berg, Kojo, Simola & Häkkinen |
The structure of fixational eye movements during straight gaze path |
| 590 |
Stevenson & Roorda |
Miniature eye movements measured simultaneously with ophthalmic imaging and a dual-Purkinje image eye tracker |
| 591 |
Schor & Bharadwaj |
A pulse-step mismatch model of dynamic ocular disaccommodation |
| 592 |
Watamaniuk & Heinen |
Opposing motion aftereffects and storage in the eye movement system |
| 593 |
Stritzke & Trommershauser |
Guidance of eye movements by vision and hand |
| 594 |
Santini, Redner, Iovin & Rucci |
A general purpose system for eye movement contingent display control |
| Natural Images |
595 |
Ripamonti, Tolhurst, Lovell & Troscianko |
Magnification factors in a V1 model of natural-image discrimination |
| 596 |
Shalev & Paradiso |
The effects of natural scenes and saccades on V1 orientation selectivity |
| 597 |
Bex, Mareschal & Dakin |
Contrast gain control in natural images |
| 598 |
Li, Sharan & Adelson |
Perceptually based range compression for high dynamic range images |
| 599 |
Chang, Stone & Backus |
Natural images and the McCullough effect |
| 600 |
Field & Chandler |
A method of estimating the information content of natural scenes |
| 601 |
Raj, Geisler, Frazor & Bovik |
Contrast statistics for foveated visual systems: Contrast constancy and fixation selection |
| 602 |
Drewes, Wichmann & Gegenfurtner |
Classification of natural scenes using global image statistics |
| 603 |
Chauvin, Fiset, Ethier, Tadros, Arguin & Gosselin |
Spatial frequency streams in natural scene categorization |
| 604 |
Cormack, Liu & Bovik |
Disparity statistics in the natural environment |
| 605 |
Conte, Han & Victor |
Processing of image statistics with and without segmentation cues |
| 606 |
Martínez Rach, Martínez Verdú, Grzywacz & Balboa |
Distribution of velocities in movies from natural human settings |
| 607 |
Takeuchi, De Valois & Saito |
Perception of temporally-filtered moving natural images |
| Visual Working Memory |
608 |
Todd & Marois |
Posterior parietal cortex activity predicts individual differences in visual short-term memory capacity |
| 609 |
Xu & Chun |
Representing objects in visual short-term memory: The roles of the human intra-parietal sulcus and the lateral occipital complex |
| 610 |
Oliver, Geiger, Lewandowski & Thompson-Schill |
Involvement of the right inferior parietal lobule in shape retrieval is modulated by prior tactile experience with objects |
| 611 |
Eng, Chen & Jiang |
Visual working memory for simple and complex visual stimuli |
| 612 |
Sledge & Olson |
Controlling the contents of visual short-term memory |
| 613 |
Flombaum & Scholl |
Visual working memory for dynamic objects: Manipulations of motion and persistence in sequential change detection |
| 614 |
Noles & Scholl |
What's in an object file? Integral vs. separable features |
| 615 |
Levinthal, Ambinder, Thomas, Gosney, Hsieh, Lipes, Wang, Crowell, Simons, Irwin, Kramer & Lleras |
The binding of features in visual short-term memory |
| 616 |
Lin, Hollingworth & Luck |
Similarity does not produce interference between visual working memory representations |
| 617 |
Woodman & Vogel |
Visual working memory consolidation is not slowed by concurrent maintenance |
| 618 |
Droll & Hayhoe |
Knowing when to remember and when to forget: Expected task relevance controls working memory use |
| 619 |
Gauchou, Vidal M., Tallon-Baudry & O'Regan |
Relational information in visual short term memory: The structural gist |
| 620 |
Delvenne |
Capacity limits in visual short-term memory within and between hemifields for colors and spatial locations |
| 621 |
Jackson & Raymond |
Visual Working Memory: Capacity is Dependent on Perceived, not Physical, Stimulus Complexity |
| 622 |
Kawasaki & Watanabe |
Interference between motion direction and color-shape in visual working memory capacity of multi-dimensional objects |
| 623 |
Liu, Palomares, Leonard & Egeth |
Subitizing capacity is decreased when visual short-term memory capacity is exceeded |
| Goal-directed hand movements |
624 |
Hudson, Landy & Maloney |
Planning movements with partial knowledge of target location encoded as a spatial prior |
| 625 |
Drewing & Trommershaeuser |
Detection and costs of force perturbations during visually-guided pointing movements |
| 626 |
Knill & McCann |
Visual feedback control of hand orientation in fast, goal-directed hand movements |
| 627 |
Schlicht & Schrater |
Optimal data fusion in the presence of sensorimotor transformation noise |
| 628 |
Crawford, Fernandez-Ruiz, Goltz, DeSouza & Vilis |
Human 'parietal reach region' encodes visual stimulus coordinates, not movement direction, during reversing prism adaptation |
| 629 |
Filimon, Nelson & Sereno |
Parietal cortex involvement in visually guided, non-visually guided, observed, and imagined reaching, compared to saccades |
| 630 |
Fattori, Breveglieri, Marzocchi, Laura & Galletti |
Monkey area V6A codes reaching movements in the three dimensional peripersonal space |
| Face Perception: Neural Mechanisms |
631 |
Jiang, Zeffiro, VanMeter, Blanz & Riesenhuber |
Predicting human face discrimination performance and FFA activation using a computational model of face neurons |
| 632 |
Yovel & Kanwisher |
The FFA shows a face inversion effect that is correlated with the behavioral face inversion effect |
| 633 |
Avidan & Behrmann |
Cortical networks mediating face familiarity and identity in the human brain |
| 634 |
Golarai, Ghahremani, Grill-Spector & Gabrieli |
Evidence for maturation of the fusiform face area (FFA) in 7 to 16 year old children |
| 635 |
Busey & Vanderkolk |
Behavioral and electrophysiological evidence for configural processing in fingerprint experts |
| 636 |
Le Grand, Bukach, Kaiser, Bub & Tanaka |
Preservation and impairment of featural and configural processing for faces as a result of prosopagnosia |
| Attentional Selection and Tracking |
637 |
Awh, Mayr & Kohnen |
Top-down control over unconscious response priming through stimuulus-specific gating |
| 638 |
Cavanagh & Holcombe |
Distinguishing pre-selection from post-selection processing limits using a moving window of selection |
| 639 |
Luck, Hopf, Boelmans, Schoenfeld, Boehler, Rieger & Heinze |
The neural site of attention matches the spatial scale of perception |
| 640 |
Scholl & Alvarez |
How does attention select and track spatially extended objects?: New effects of attentional concentration and amplification |
| 641 |
Alvarez & Franconeri |
How many objects can you track? Evidence for a flexible tracking resource |
| 642 |
Halberda & Feigenson |
Counting without individuals: Rapid parallel enumeration of sets implicates preattentive object files |
| 643 |
Seiffert |
Attentional tracking across display translations |
| Sensory Integration |
644 |
Nawrot & Stockert |
Motion parallax in movies: Background motion, eye movement signals, and depth |
| 645 |
Ren, Khan & Crawford |
Guiding the eye with the hand: Role of proprioception in spatial updating for saccades |
| 646 |
Bruno, Jacomuzzi, Del Bello & Dell' Anna |
Ames' window, vision, and proprioception |
| 647 |
Beierholm, Quartz & Shams |
The ventriloquist illusion as an optimal percept |
| 648 |
Baumann & Greenlee |
Neural correlates of coherent audio-visual motion perception |
| 649 |
Schutz & Kubovy |
Seeing music, hearing gestures |
| 650 |
Ernst |
From independence to fusion: A comprehensive model for multisensory integration |
| Motion 2 |
651 |
Allison, Macuda, Jennings, Thomas, Guterman & Craig |
Detection of motion-defined form in the presence of veiling noise |
| 652 |
Bressler & Whitney |
Second-order motion shifts apparent position |
| 653 |
Cai |
Compression of perceived motion trajectories |
| 654 |
Caplovitz, Hsieh & Tse |
The neural correlates of motion processing on the basis of trackable features |
| 655 |
Choi & Scholl |
Can the perception of causality be measured with representational momentum? |
| 656 |
Loffler, Magnussen, Orbach & Gordon |
The case of the misperceived saltire: Oblique motion of two intersecting lines is biased |
| 657 |
Nichols & Hock |
The contributions of edges and surfaces to the perception of object motion |
| 658 |
Yamada, Kawabe & Miura |
Spin-orbit coupling in vision: Evidence from representational displacement |
| 659 |
Bayerl & Neumann |
Attention and figure-ground segregation in a model of motion perception |
| 660 |
Budnik, Speck, Kaller, Hamburger, Pinna & Hennig |
Neural correlates of illusory motion perception in the Pinna-figure |
| 661 |
Dal Martello, Maloney, Sahm & Spillmann |
How the past gives way to the present: Evidence for Bayesian updating with repeated presentation of ambiguous motion quartets |
| 662 |
Armstrong, Lewis & Maurer |
Moving into adult vision: five-year-olds' immaturities in detecting second-order motion versus discriminating its direction |
| 663 |
Bower, Ni & Andersen |
Aging and the detection of motion direction in random-dot stimuli |
| 664 |
Ni, Andersen & Lin |
Spatio-temporal integration, kinetic occlusion and aging |
| 665 |
Goltz, Whitney & Vilis |
A differential origin-of-motion response in V1 for first-order, but not second-order stimuli as revealed by fMRI |
| 666 |
Kozak, Formisano, Backes, Teixeira, Xavier, Goebel & Castelo-Branco |
Neural correlates of illusory motion perception: The influence of apparent motion on plaid motion aftereffects |
| 667 |
Lee, Jang & Lee |
Direction tuning curves of motion adaptation in the visual cortex revealed by an event-related fMRI study |
| 668 |
McDonald & Kourtzi |
Perception of motion induction for naturalistic images in the human visual cortex |
| Neural Coding |
669 |
Anderson & DeAngelis |
Redundant populations of simple cells represent wavelet coefficients in monkey V1 |
| 670 |
Yang & Purves |
The neural code for luminance |
| 671 |
Cadieu, Kouh, Riesenhuber & Poggio |
Shape representation in V4: Investigating position-specific tuning for boundary conformation with the standard model of object recognition |
| 672 |
Michel & Jacobs |
The costs of ignoring high-order correlations in populations of model neurons |
| 673 |
Baldo |
A vectorial model of sensory perception |
| 674 |
Zetzsche, Nuding & Schill |
Nonlinear overcomplete coding in visual cortex |
| 675 |
Zhou, Samonds, Bernard & Bonds |
Synchronous activity in cat visual cortex encodes collinear and cocircular contours |
| 676 |
Bernard, Samonds, Zhou & Bonds |
An integration model for detection and quantification of synchronous firing within cell groups |
| 677 |
Alford & Marrocco |
Latency derived receiver operating characteristics support a neural integration model of decision making |
| Neural Mechanisms and Models of Attention |
678 |
Dean & Platt |
Persistent neuronal activity for remembered visual targets in macaque posterior cingulate cortex |
| 679 |
Chaumon, Vidal, Hugueville & Tallon-Baudry |
The time course of sensory amplification by feature-based attention: A direct measure on frequency-tagged evoked responses |
| 680 |
Bolbecker, Lim, Li, Traverso, Orchard, Christadoss, Brahmbhatt, Beck, Lewis, Fleet, Carlson, Hoyt, Collins, Jr., Swan & Wasserman |
Are photoreceptors in the attention spotlight? Efferent neuromodulators accelerate and/or retard the time course of photoreceptor responses evoked by light |
| 681 |
Zhang, Ferrera, Hood & Hirsch |
The effect of attention and contrast on the BOLD response in V1 and beyond |
| 682 |
Marti & Richer |
Differential visual cortex activity associated with common-onset and delayed-onset masks |
| 683 |
Carter, Burr, Pettigrew & Vollenweider |
Using psilocybin to investigate the relationship between attention, working memory and the serotonin 5-HT1A and 5-HT2A receptors |
| 684 |
Battelli, Cavanagh, Schomer & Barton |
Temporary bilateral deficit of transient visual attention after right inferior parietal lobe surgery: A single case study |
| 685 |
Vickery & Jiang |
Attention and competitive decision making |
| 686 |
Ling & Carrasco |
Contrast gain vs. response gain: Do sustained and transient covert attention exhibit different signature responses? |
| 687 |
Canto-Pereira, Rocha & Ranvaud |
Is Stochastic Simulation a Suitable Geostatistical Method for the Study of Visual Attention? |
| 688 |
Gorea & Sagi |
Characterizing attention in terms of changes of decision criterion and sensitivity |
| 689 |
Koike & Saiki |
Multiplicative visual attention model can account for attentional modulation on STA power spectrum |
| Orienting and Eye Movements |
690 |
Shomstein & Behrmann |
Goal-directed attentional orienting in patients with dorsal parietal lesions |
| 691 |
Dannemiller |
A contrast polarity heterogeneity effect in infant visual orienting |
| 692 |
Peters, Iyer, Koch & Itti |
Components of bottom-up gaze allocation in natural scenes |
| 693 |
Myers |
Toward a method of objectively determining scanpath similarity |
| 694 |
Ziegler & Kerzel |
Exogenous and endogenous attention shifts during smooth pursuit eye movements |
| 695 |
Wallman, Madelain & Krauzlis |
Can target selection for saccades use separate foci of attention in the two hemispheres? |
| 696 |
Khan, Crawford & Martinez-Trujillo |
Attention modulates saccade latency but not kinematics |
| 697 |
Jie & Clark |
Microsaccadic eye movements during ocular pursuit |
| 698 |
Najemnik & Geisler |
Eye movement statistics for optimal, sub-optimal and human visual searchers |
| 699 |
Shneor & Hochstein |
Eye dominance effects in feature search |
| 700 |
Zelinsky, Dickinson, Chen, Neider & Brennan |
Collaborative search using shared eye gaze |
| Bistable Perception |
701 |
McArthur & Mamassian |
Temporal dynamics of bistability in motion transparency |
| 702 |
Juergen, Heiko W & Michael |
Ambiguous Figures: Effects of ISIs in discontinuous stimulus presentation on EEG components |
| 703 |
Pearson & Clifford |
When your brain decides what you see: Grouping across monocular, binocular and stimulus rivalry |
| 704 |
van Dam & van Ee |
The role of eye movements in bistability from perceptual and binocular rivalry and the role of voluntary control |
| 705 |
Kanai & Verstraten |
Rapid plasticity determines the percept for a forthcoming bistable stimulus |
| 706 |
White |
Mutual information and stochastic resonance in multistable percepti |
| 707 |
van Ee |
Visual awareness and voluntary control |
| Perceptual Learning 1 |
708 |
Huxlin, Williams, Sullivan & Hayhoe |
Training-induced improvements of visual motion perception after V1 cortical damage in humans |
| 709 |
Notman & Sowden |
Learned categorical perception specific to retinal location and orientation |
| 710 |
Jeter, Dosher, Petrov & Lu |
Identical transfer of perceptual learning following easy and difficult task training |
| 711 |
Thompson, Lu & Liu |
Perceptual learning of motion discrimination with suppressed and un-suppressed MT |
| 712 |
Suchow & Pelli |
Learning to identify letters: Generalization in high-level perceptual learning |
| 713 |
Nanez, Seitz, Holloway & Watanabe |
Subliminal perceptual learning of motion results in improvements of critical flicker fusion thresholds |
| 714 |
Yamagishi, Seitz, Werner, Kawato & Watanabe |
Task specific disruption of perceptual learning |
| Lateral interactions and filling-in |
715 |
Otte, Spillmann, Hamburger, Brüning, Mader & Magnussen |
Filling-in of the blind spot: How much information is needed? |
| 716 |
Sasaki & Watanabe |
The primary visual cortex fills in color |
| 717 |
Yokota & Yokota |
Facilitation of perceptual filling-in for spatio-temporal frequency of dynamic textures |
| 718 |
Wu, Kanai & Shimojo |
Ability of contours to block rapid color filling-in is dependent on global configuration |
| 719 |
Devinck, Delahunt, Hardy, Spillmann & Werner |
Color assimilation: Dependence of watercolor spreading on contour luminance contrast and stimulus width |
| 720 |
Spillmann, Hindi-Attar, Leinenkugel & Hamburger |
Texture fading correlates with neuronal response strength |
| 721 |
Verghese, Petrov & McKee |
Collinear facilitation is largely due to uncertainty reduction |
| 722 |
Mihaylov, Manahilov, Simpson & Strang |
Transfer of noise over long distances |
| 723 |
Hayakawa, Tanaka, Miyauchi, Misaki & Tashiro |
Assymetrical long-range interaction reversed with adaptation to upside-down reversed optical transformation |
| 724 |
Tanaka, Miyauchi, Misaki, Hayakawa & Tashiro |
Asymmetrical long-range interaction between upper and lower visual hemifields |
| 725 |
Sagi, Judelman & Bonneh |
Contrast detection thresholds of gabor strings: Configuration dependency |
| Motion in Depth 2 |
726 |
Calabro, Beardsley & Vaina |
The contribution of disparity to motion contrast segmentation |
| 727 |
Artemenkov |
Phenomena of the asymmetric process of visual perception for dilating and contracting size-changing objects in different time limited conditions |
| 728 |
Barton & Cohn |
Multiphasic impulse response for 2D longitudinal motion |
| 729 |
Hosokawa, Ohtsuka & Sato |
Depth perception from intermittent motion parallax stimuli |
| 730 |
Yonas, Zimmerman, Seo, Alexander, Olinick & Polley |
The effect of luminance contrast and stroboscopic presentation on the threshold for the discrimination of approach from withdrawl |
| 731 |
McBeath, Dolgov & Sugar |
The axis of an american football leads observers to misjudge where it is headed |
| 732 |
Sakano, Allison & Howard |
Aftereffects of motion in depth based on binocular cues |
| 733 |
Field & Wann |
Perceiving time to collision activates sensorimotor cortex |
| 734 |
Thibodeau, Gromko & Durgin |
Walking and the role of speed in the perception of time to contact |
| Object Recognition |
735 |
Santos, Barnes & Mahajan |
Numerical representation in four lemur species |
| 736 |
Phillips, Shankar & Santos |
Evidence of kind representations in the absence of language from two monkey species |
| 737 |
Sinha, Balas & Ostrovsky |
Project DYLAN: Modeling the development of visual object concepts |
| 738 |
Fazl, Grossberg & Mingolla |
Invariant object learning and recognition using active eye movements and attentional control |
| 739 |
Liu & Lu |
Against image-based theories of shape recognition |
| 740 |
Hayworth & Biederman |
Differential fMRI activity produced by variation in parts and relations during object perception |
| 741 |
Biederman & Hayworth |
fMRIa to complementary, contour-deleted images of objects |
| 742 |
Serre & Poggio |
Standard model v2.0: How visual cortex might learn a universal dictionary of shape components |
| 743 |
Andresen & Grill-Spector |
Mixture of view-invariant and view-dependent representations in human object-selective cortex |
| 744 |
Murray, Boyaci & Kersten |
The emergence of object size invariance in the human visual cortex |
| 745 |
Leek & Johnston |
The role of polar features in visual object constancy |
| 746 |
Harris & Dux |
Paying attention to orientation: A two-stage framework of familiar object recognition |
| Sensory Integration: Vision and Touch |
747 |
Bakdash, Augustyn & Proffitt |
Effects of effort and reduced visual cue information on percieved walking speed |
| 748 |
Brown, Kroliczak, Halpert & Goodale |
A hand in sight: How blindsight is improved by hand location |
| 749 |
Dunphy, Evans, Klostermann & Durgin |
Visuo-spatial alignment produces an instant rubber hand illusion |
| 750 |
Helbig & Ernst |
Looking in the mirror does not prevent multimodal integration |
| 751 |
May, Flanagan, Foss, Simoneaux & Dobie |
Visual and vestibular factors in the perception of bodily tilt |
| 752 |
Oh & Li |
Effects of response type on visuotactile congruency effects |
| 753 |
Takahashi & Saiki |
Combining multi-modal information of a deformation of an object |
| 754 |
Violentyev, Shimojo & Shams |
Touch-induced visual illusion |
| 755 |
Norman, Norman, Herrmann & Crabtree |
Aging and the cross modal perception of natural object shape |
| 756 |
Azoulai & Ramachandran |
Blind patients “see” their moving hand in darkness (synesthesia) |
| 757 |
Klier, Angelaki & Hess |
Gravitational signals contribute to visuospatial updating in humans |
| Temporal Processing |
758 |
Bodelon, Fallah & Reynolds |
Temporal resolution of the human visual system for processing color, orientation, and color/orientation conjunctions |
| 759 |
D'Antona & Shevell |
Nonlinear neural processing of temporally modulated inducing light |
| 760 |
Wolfson & Graham |
Dynamics of contrast-gain controls in pattern vision |
| 761 |
Scharnowski & Herzog |
Feature integration is determined by the temporal order of events |
| 762 |
Francis |
The role of temporal integration in backward masking |
| 763 |
Cho & Francis |
The highs and lows of temporal integration in backward masking |
| 764 |
Hermens, Luksys, Gerstner & Herzog |
Visual backward masking: Feed-forward or recurrent? |
| 765 |
Johnston, Arnold & Nishida |
Spatially localised distortions of perceived duration |
| 766 |
Mizokami & Crognale |
Detection of dual flashing lights |
| 767 |
Eagleman, Lakhani & Stetson |
How do motor acts change time perception? |
| 768 |
Carmel, Lavie & Rees |
Neural correlates of conscious flicker perception |
| 769 |
Stetson, Cui, Montague & Eagleman |
Illusory reversal of action and sensation elicits neural conflict response |
| 3D visual processing |
770 |
Brown, Lindsey, Miracle & Satgunam |
D-max for stereopsis in human infants |
| 771 |
Norcia & Hou |
Random-dot stereopis is highly immature in infants |
| 772 |
Wilcox, Wildes, Lakra & Spengler |
The contribution of binocular and monocular texture elements to depth ordering |
| 773 |
Lovell, Troscianko & Parraga |
Distance judgements based on rayleigh scattering: The detection of color changes with distance in blue-yellow opponent channels |
| 774 |
Banks, Burge & Schlerf |
Disparity and texture gradients are combined in a slant estimate and a homogeneity estimate |
| 775 |
Georgieva, Todd, Peeters & Orban |
Functional neuroanatomy for the processing of 3D shape from shading and texture in humans |
| Visual Search |
776 |
Itti & Baldi |
A surprise theory of early attention |
| 777 |
Rosenholtz & Jin |
A computational form of the statistical saliency model for visual search |
| 778 |
Geisler & Najemnik |
Human and optimal eye movement strategies in visual search |
| 779 |
Wolfe, Kenner & Horowitz |
Visual search: The perils of rare targets |
| 780 |
Saiki |
Features underlying visual search asymmetry revealed by classification images |
| 781 |
Ipata, Gee, Bisley & Goldberg |
Top-down inhibition of the response to an irrelevant popout stimulus in monkey parietal cortex |
| Color, lighting, and objects |
782 |
Xiao, Kanyuk & Brainard |
Color appearance and the material properties of three-dimensional objects |
| 783 |
Johnson, Kingdom, Olmos & Baker Jr. |
Spatiochromatic statistics of natural scenes: First- and second-order information and their correlational structure |
| 784 |
Hansen & Gegenfurtner |
Color discrimination of natural objects |
| 785 |
Doerschner, Boyaci & Maloney |
Representing spatially and chromatically varying illumination using spherical harmonics in human vision |
| 786 |
Maloney, Boyaci & Doerschner |
Representing the spatial and chromatic distribution of the illuminant in scenes with multiple punctate chromatic light sources |
| 787 |
Hurlbert & Ling |
If it's a banana, it must be yellow: The role of memory colors in color constancy |
| Scene Perception and Inattentional Blindness |
788 |
Most & Astur |
Attentional set as a contributing factor in virtual traffic accidents |
| 789 |
Beck, Peterson & Angelone |
The roles of attention, memory, comparison failures, and decision making in top-down influences on change detection |
| 790 |
Rensink |
Robust inattentional blindness |
| 791 |
Sampanes & Bridgeman |
Undetected transformation of one scene into another of the same gist |
| 792 |
Simons, Slichter, Lleras, Martinez-Conde, Nevarez & Caddigan |
Induced fading of natural scenes |
| 793 |
Potter & Fox |
Forgetting visual versus conceptual information about pictures |
| 794 |
Bravo & Farid |
The depth of distractor processing in search through clutter |
| Binocular vision/eye movements |
795 |
Forte |
Binocular summation of color and luminance contrast gratings |
| 796 |
Ishii, Tang & Tamura |
Empirical horizontal horopter determined by fusion time |
| 797 |
Georgeson, Meese & Baker |
Binocular summation, dichoptic masking and contrast gain control |
| 798 |
Simpson & Manahilov |
Two eyes: Twice as good as one? |
| 799 |
Vedamurthy, Suttle, Alexander & Asper |
Binocular interactions of spatial visual signals in children |
| 800 |
Howe & Livingstone |
Binocular vision and the correspondence problem |
| 801 |
Kanagaraj & Stevenson |
The role of luminance polarity in vergence control |
| 802 |
Sheliga, FitzGibbon, Kodaka & Miles |
Vertical disparity vergence eye movements: Evidence for spatial filtering of the monocular visual inputs prior to binocular matching |
| Reading & Print |
803 |
Florer, Salvano-Pardieu & Lampkin |
Memory for words from fictional text read on computer screens and paper, in four polarities |
| 804 |
Yu, Cheung, Legge & Chung |
Changes in the visual span may explain the effect of letter spacing on reading speed |
| 805 |
Caspi & Zivotofsky |
Multi-word buffering during bilingual bidirectional reading as evidenced by saccade direction reversals |
| 806 |
Pelli, Su, Berger, Majaj, Martelli, Guo & Tillman |
Crowding, shuffling, and capitalizing reveal three processes in reading |
| 807 |
Kwon, Legge & Dubbels |
Developmental changes in the visual span for reading |
| 808 |
Lu, Sperling, Manis & Seidenberg |
Deficits in forming perceptual templates may underlie the etiology of developmental dyslexia |
| 809 |
Geiger & Poggio |
Preventing dyslexia? Early enhanced hand-eye coordination activities reduces reading difficulties |
| 810 |
Shovman & Ahissar |
Isolating the role of visual perception in dyslexia |
| 811 |
Daniel, Alan, Nicolas, Caroline, Martin & Frederic |
Use of spatial frequencies information in normal readers and a letter-by-letter dyslexic patient |
| 812 |
Scharff & Ahumada |
Why is light text harder to read than dark text? |
| 813 |
Caroline, Daniel, Alan, Martin & Frederic |
The effective use of spatial frequencies through time in reading |
| 814 |
Yokosawa |
Critical role of phonological encoding in midstream order deficit |
| 815 |
Yu, Zhang, Kuai & Liu |
Recognition of chinese characters: The effects of stroke frequency and critical band masking |
| 816 |
Jacobson & Sejnowski |
Enhancing fonts |
| 817 |
Cohn & Tammero |
What matters in the matter of variable message sign intelligibility |
| Faces 2 |
818 |
Hussain, Bennett & Sekuler |
The role of sleep in perceptual learning of face-identification |
| 819 |
Rousselet, Husk, Bennett & Sekuler |
200 ms of controversies: A high-density ERP study of face processing |
| 820 |
Husk, Rousselet, Bennett & Sekuler |
Eccentricity effects on the N170 face ERP component can be eliminated by size scaling |
| 821 |
Gaspar, Sekuler & Bennett |
Upright & inverted face recognition relies on the same, narrow band of spatial frequencies |
| 822 |
McKone, Edwards, Robbins & Anderson |
The stickiness of face adaptation aftereffects |
| 823 |
Eger, Schweinberger, Dolan & Henson |
Familiarity enhances invariance of face representations in human ventral visual cortex |
| 824 |
Gobbini, Gentili, Pietrini, Ricciardi, Guazzelli & Haxby |
Distributed representation of facial expression in the superior temporal sulcus: An fMRI study |
| 825 |
Peelen & Downing |
Cortical representation of faces, bodies and their parts |
| 826 |
Watson, Rhodes & Clifford |
Face adaptation contingent on orientation |
| 827 |
Holub, Everingham, Zisserman & Perona |
Combining principal component techniques and psychological spaces to find perceptually similar faces |
| 828 |
Mermillod, Alleysson, Bert, Guyader & Marendaz |
Low spatial frequency channels are more useful than high spatial frequency channels in classifying face emotional expressions, simulation of fMRI data |
| 829 |
Collin, O'Byrne & Wang |
Effects of image background on spatial frequency thresholds for face recognition |
| 830 |
Leopold, Rhodes, Mueller & Jeffery |
The dynamics of visual adaptation to faces |
| 831 |
Therrien & Collin |
Middle spatial frequencies are needed for face recognition only when learned faces are unfiltered: More evidence from spatial frequency thresholds for matching |
| 832 |
Yasuda, Bedard, Mizokami, Kaping & Webster |
Adaptation and individual differences in categorical judgments of faces |
| 833 |
Kovács, Zimmer, Harza, Bankó, Antal & Vidnyánszky |
Testing for translation invariance reveals two stages of facial adaptation |
| Motion 3 |
834 |
Berzhanskaya, Grossberg & Mingolla |
Depth-tuning of occluded moving objects by boundary selection of motion signals |
| 835 |
Bukowski & Hock |
Context effects in the perception of collinear motions: Spatial anistropy and non-local effects of attention |
| 836 |
Caclin & Lorenceau |
Form/motion binding with and without eye-movements |
| 837 |
Dakin, Mareschal & Bex |
Equivalent noise and reverse correlation analysis reveals inhibitory interactions between channels coding global direction |
| 838 |
Lorenceau & Lalanne |
Adaptive strategies for perception-action coupling |
| 839 |
Sikoglu & Vaina |
Effect of directional noise on heading perception |
| 840 |
Zwicker & Giaschi |
Speed-tuned global motion mechanisms |
| 841 |
Morya, Savelsbergh, Ferlazzo & Ranvaud |
Motion perception and temporal precision in a time-to-contact task |
| 842 |
Baek & Sajda |
A probabilistic network model of the influence of local figure-ground representations on the perception of motion |
| 843 |
Dong |
Sensory-motor integration during free-viewing natural time-varying images: A theory of dynamic processing in visual systems |
| 844 |
Amano, Nishida, Ohtani, Goda, Ejima & Takeda |
Predicting manual reaction time to visual motion by temporal integrator model of meg response |
| 845 |
Heinen, Rowland, Velisar & Wade |
Cortical evaluation of a rule-based trajectory revealed by fMRI |
| 846 |
Miles, Sheliga & FitzGibbon |
The initial ocular following response (OFR) to moving grating patterns: Evidence for winner-take-all mechanisms |
| 847 |
Sarkheil, Jastorff, Giese & Kourtzi |
Categorization of complex dynamic patterns in the human brain |
| 848 |
Giaschi, Edwards, Au Young & Bjornson |
Asymmetrical cortical activation by global motion in children with dyslexia |
| 849 |
Kanazawa, Shirai, Otsuka & Yamaguchi |
Perceptual development of motion transparency in 3- to 5- month-old infants |
| 850 |
O'Brien, Spencer & Tsermentseli |
Form and motion processing in dyslexia |
| Object Recognition in Context |
851 |
Fenske, Boshyan & Bar |
Can a gun prime a hairbrush? The “initial guesses” that drive top-down contextual facilitation of object recognition |
| 852 |
Boshyan, Fenske, Aminoff & Bar |
Cortical manifestations of context-related facilitation of visual object recognition |
| 853 |
Gronau, Neta & Bar |
Combined and dissociable effects of spatial and semantic contextual information on visual object recognition |
| 854 |
Heinrich & Grill-Spector |
Temporal dynamics of object-repetition effects in the human visual cortex |
| 855 |
Kim & Tong |
Human ventral temporal areas contain flexible position-invariant information about subordinate-level objects |
| 856 |
Zhou, Hayward & Harris |
Viewpoint representation in object recognition: Evidence from repetition blindness |
| 857 |
Buffat, Roumes & Lorenceau |
Repetition blindness with natural images |
| 858 |
Garsoffky, Schwan & Huff |
Is recognition of visual sequences better if canonical viewpoints are used? |
| 859 |
Christensen & Todd |
The seductive effect of context on object recognition |
| Perceptual Learning 2 |
860 |
Brady & Chun |
The effects of local context in visual search: A connectionist model and behavioral study of contextual cueing |
| 861 |
Chung, Levi & Li |
Learning to identify contrast-defined letters in peripheral vision |
| 862 |
Dupuis-Roy & Gosselin |
Examining the top-down component of perceptual learning |
| 863 |
Qi, Backus, Stone, Saunders & Marshall |
Recruitment of new perceptual cues |
| 864 |
Seitz, Nanez, Holloway, Koyama & Watanabe |
Seeing what isn't there; The costs of perceptual learning |
| 865 |
Sowden & Notman |
Categorical Perception: Categorisation Dependent Perceptual Learning |
| 866 |
Vomela & Peterson |
Better contextual memory for dense displays |
| 867 |
Wenger & Rasche |
Bias in an unbiased land? Criterion shifts in perceptual learning using two-interval two-alternative forced-choice staircase procedure |
| 868 |
Bhatt, Carpenter & Grossberg |
Learning and recognition of textured objects |
| 869 |
Sawada & Kaneko |
Visual learning and the selection of perceived shape from shading |
| 870 |
Chu, Lu, Dosher & Lee |
Independent perceptual learning in monocular and binocular motion systems |
| 871 |
Burge, Ernst & Banks |
Localization, not perturbation, affects visuomotor recalibration |
| Sensory Integration: Vision and Hearing |
872 |
Rosenthal, Abdarbashi & Shams |
Plasticity in auditory-visual integration |
| 873 |
Chen & Yeh |
Visual token individuation by sound in repetition blindness |
| 874 |
Evans & Treisman |
Crossmodal binding of audio-visual correspondent features |
| 875 |
Ichikawa & Masakura |
Auditory stimulation modifies the apparent motion |
| 876 |
Koene, Fujisaki, Arnold, Johnston & Nishida |
Cross modal correlation search in the presence of visual distractors |
| 877 |
Mamassian |
Auditory tones influence perceived speed in apparent motion |
| 878 |
McCormick & Mamassian |
Response biases in the illusory-flash effect |
| 879 |
Schirillo & Mays |
Lights can reverse auditory localization |
| 880 |
Smith, Grabowecky & Suzuki |
Pitch of concurrent pure tone influences visual gender perception |
| 881 |
Turano & Chaudhury |
Implicit auditory signal can scale men's egocentric spatial representation |
| 882 |
Bertz, Li & Matin |
The influences of visual pitch on visually perceived eye level, visually perceived pitch, felt head orientation, and felt hand orientation |
| 883 |
Conrey & Gold |
An ideal observer analysis of variability in visual-only speech |
| 884 |
Watkins, Shams, Haynes & Rees |
Sound-induced illusory flash perception modulates V1 activity |
| 885 |
Beer & Röder |
Attending to visual or auditory motion affects perception within and across modalities: An event-related potential study |
| 886 |
Doucet, Bergeron & Lepore |
Neurophysiological changes in the visual cortex after cochlear implantation |
| 887 |
Jordan, Brannon, Logothetis & Ghazanfar |
Monkeys match the number of voices they hear to the number of faces they see |
| Visual cortical organization |
888 |
Wielaard & Sajda |
The role of the LGN on the spatial frequency dependence of surround suppression in V1: Investigations using a computational model |
| 889 |
James, Goh, Henriksson & Vanni |
Multifocal 60 region fMRI mapping of human visual cortex |
| 890 |
Goh, James, Henriksson & Vanni |
Multifocal 60 region fMRI derivation of the 3D structure and magnification factor of human primary visual cortex |
| 891 |
Bomberger & Schwartz |
The structure of cortical hypercolumns: Receptive field scatter may enhance rather than degrade boundary contour representation in V1 |
| 892 |
Ales, Carney & Klein |
Multifocal VEP signal dependence on stimulus area |
| 893 |
Dandekar, Ales, Carney & Klein |
Cortical folding as a sparseness criterion for identifying vep sources |
| 894 |
Awater, Kerlin & Tong |
Cortical representation of space around the blind spot |
| 895 |
Wagner, Polimeni & Schwartz |
Gibson, meet topography: The dipole structure of extra striate cortex facilitates navigation via optical flow |
| 896 |
Tyler |
Enhanced concepts of occipital retinotopy |
| 897 |
Schira, Wade, Kontsevich & Tyler |
Geometric and metric properties of visual areas V1 and V2 in humans |
| 898 |
Polimeni, Hinds, Balasubramanian, van der Kouwe, Wald, Dale, Fischl & Schwartz |
Two-dimensional mathematical structure of the human visuotopic map complex in V1, V2, and V3 measured via fMRI at 3 and 7 Tesla |
| 899 |
Lee & Lee |
Dynamics of line motion illusion reflects the anatomical and functional architecture of the early visual cortex |
| 900 |
Harner & Watanabe |
A self-organizing neural network model of the development of motion direction selectivity, orientation, and ocular dominance maps and receptive fields in V1 and MT |
| 901 |
Dilks & McCloskey |
The El Greco effect: Perceptual distortion from visual cortical reorganization |
| 902 |
Renier, Collignon, Poirier, Tranduy, Vanlierde, Bol, Veraart & De Volder |
Cross-modal activation of visual cortex during depth perception using auditory substitution of vision |
| 903 |
Smith, Gosselin & Schyns |
Rendering visual representations from oscillatory brain activity |
| 904 |
Haushofer, Baker & Kanwisher |
Greater sensitivity to convexities than concavities in human lateral occipital complex |
| 905 |
Kim, Ducros, Ugurbil & Kim |
Topography of high-order human object areas measured with DTI and fMRI |
| 906 |
Samco, Caplovitz, Hsieh & Tse |
Neural correlates of human creativity revealed using diffusion tensor imaging |
| Objects: Cortical Mechanisms |
907 |
Aminoff, Gronau & Bar |
The parahippocampal cortex mediates both spatial and non-spatial associative processing |
| 908 |
Kiper |
Responses of V4 neurons to colored glass patterns |
| 909 |
Motter |
Sensitivity of V4 neurons to sequences of letter-like stimuli |
| 910 |
Trujillo, Peterson & Allen |
Electrophysiological evidence for early access to object memories during figure assignment in humans |
| 911 |
Stanley & Rubin |
Functionally distinct sub-regions in the lateral occipital complex revealed by fMRI responses to abstract 2-dimensional shapes and familiar objects |
| Visual Memory |
912 |
Dosher, Liu & Lu |
The decay of perceptual representations in iconic memory |
| 913 |
Olson, Chatterjee, Page & Verfaellie |
Binding in visual short term memory is impaired in patients with medial temporal lobe amnesia |
| 914 |
Shim, Alvarez & Jiang |
Capacity limit of visual working memory in parietal cortex reflects capacity limit of spatial selection |
| 915 |
Sekuler & Yotsumoto |
Voluntary amnesia: Putting sights out of mind |
| 916 |
Hollingworth |
Preserved memory for scene brightness following an undetected change |
| Looking, decisions, search |
917 |
Eckstein, Drescher & Shimozaki |
Attentional cues in real scenes, saccadic targeting and Bayesian priors |
| 918 |
Burr, Morrone & John |
Saccadic eye-movements cause relativistic compression of time as well as space |
| 919 |
Marendaz, Chauvin & Hérault |
A causal link between scene exploration, local saliency and scene context |
| 920 |
Rothkopf, Ballard, Sullivan & de Barbaro |
Bayesian modeling of task dependent visual attention strategy in a virtual reality environment |
| 921 |
Renninger, Verghese & Coughlan |
Modeling eye movements in a shape discrimination task |
| 922 |
Ludwig, Gilchrist, McSorley & Baddeley |
Visual sampling and saccadic decisions: A reverse correlation approach |
| 923 |
Grinband, Hirsch & Ferrera |
Functional imaging of categorical decision processes |
| Motion |
924 |
Moore & Enns |
The path of least persistence: Disrupting object continuity causes a release from motion deblurring |
| 925 |
Watanabe & Shimojo |
Dynamic, not static, mae follows the illusory percept |
| 926 |
Appelbaum, Lu & Sperling |
Neuromagnetic responses to first- and second-order motion |
| 927 |
Krekelberg, van Wezel & Albright |
The vector-average readout model of MT fails to account for contrast-induced changes in speed perception |
| 928 |
Stocker & Simoncelli |
Constraining the prior and likelihood in a Bayesian model of human visual speed perception |
| 929 |
Thompson & Anstis |
Retracing our footsteps: A revised theory of the footsteps illusion |
| 930 |
Sato & Maruya |
Local motion speed affects the perceived speed of motion-defined motion |
| Biological Motion 2 |
931 |
Hadjigeorgieva, Jang & Pollick |
The effect of perception of complex human movement on late event-related brain responses |
| 932 |
Jastorff, Kourtzi & Giese |
Neural plasticity mechanisms for learning of biological motion |
| 933 |
Chouchourelou, Matsuka, Kozhevnikov, Hanson & Shiffrar |
The visual analysis of bodily emotions |
| 934 |
Jokisch, Daum, Koch, Schwarz & Troje |
Biological motion versus coherent motion perception: The role of the cerebellum |
| 935 |
Knapp & Corina |
Biological motion perception in deaf signers and hearing non-signers |
| 936 |
McAleer, Paterson, Mazzarino & Pollick |
Towards canonical views of animacy from scenes of human action |
| 937 |
Paterson, Ma & Pollick |
A library of human movements for the study of identity, gender and emotion perception from biological motion |
| 938 |
Pollick, Ma, Tsao & Nixon |
Attitudinal and biometric contributions to the recognition of identity from point-light walkers |
| 939 |
Sebanz, Kozhevnikov & Shiffrar |
Unintentional movements during action observation: Copying or compensating? |
| 940 |
Johnson |
How perceptions of body motion and morphology affect complex social judgments |
| 941 |
Prasad, Loula & Shiffrar |
Person recognition across multiple viewpoints |
| 942 |
Roether & Giese |
Integration of synergies in visual recognition of emotional human walking |
| 943 |
Sadr, Troje & Nakayama |
Attractiveness, averageness, and sexual dimorphism in biological motion |
| Visual Search |
944 |
Sung |
Distinguishing serial and parallel processing in visual search without depending on set size effect |
| 945 |
Ogawa & Kumada |
Coarse-to-fine encoding of contextual information in visual search |
| 946 |
Leber & Chun |
Why search for singletons when you know the target feature? |
| 947 |
Morgan & Solomon |
Attentional capacity limit for visual search causes spatial neglect in normal observers |
| 948 |
Flusberg, Kunar & Wolfe |
In visual search, can the average features of a scene guide attention to a target? |
| 949 |
Davis, Main & Hailston |
Searching for search asymmetries with simple and complex stimuli |
| 950 |
Gosney & McCarley |
Predictive metacognitive judgments in a visual search task |
| 951 |
Guyader, May & Zhaoping |
Top-down interference in visual search |
| 952 |
Lleras & Enns |
Rapid resumption of visual search is more than lucky spatial orienting |
| 953 |
Nam & Cha |
Efficiency of visual search are closely related with several properties of oval shape |
| 954 |
Schoonveld, Eckstein & Shimozaki |
Optimal and suboptimal models of oddity search |
| 955 |
Shive & Francis |
Using models of visual search to design optimal interfaces |
| 956 |
Vlaskamp & Hooge |
Crowding degrades saccadic search performance |
| 957 |
Koning & Van Lier |
In search of segmentation |
| 958 |
Toyofuku & Schatzki |
Feasibility of feature-based contraband detection in x-ray images |
| 959 |
May & Zhaoping |
Both cognitive factors and local inhibition mediate the effect of a surrounding frame in visual search for oriented bars |
| Perceptual Organization 2 |
960 |
Ogmen & Herzog |
Spatio-temporal integration in grouping-based feature attribution |
| 961 |
Newman & Junge |
The perception of order: Same-different paradigm reveals a relationship between goodness-of-figure and processing efficiency |
| 962 |
Moradi & Shimojo |
Adaptation to invisible gratings in Troxler filling-in |
| 963 |
Fahrenfort, Scholte & Lamme |
Masking interrupts feedback processing |
| 964 |
Butcher & Cavanagh |
Within-field advantage for detecting matched motion paths |
| 965 |
Gomez, Caplovitz, Hsieh & Tse |
Neuronal correlates of common fate (spatial and temporal correlation) in retinotopic cortex |
| 966 |
Ostrovsky & Sinha |
Object binding through motion |
| 967 |
Guttman, Gilroy & Blake |
Temporal information for spatial grouping: Structure or synchrony? |
| 968 |
Scholte, Sligte & Lamme |
Neural correlates of edge detection and scene segmentation during inattentional blindness |
| 969 |
Chubb & Wright |
A regular grid imposes a city-block metric on visual space |
| 970 |
Ghose & Palmer |
Surface convexity and extremal edges in depth and figure-ground perception |
| 971 |
Lipes & Vecera |
The effect of skew symmetry on figure-ground assignment |
| 972 |
Lai, Akin, Chan, Patel & Hirsch |
Local and global systems revealed in image segmentation during bistable percepts of three ambiguous figures: “Schroeder's Staircase”, the “Rubin Face-Vase figure”, and the “Ebbecke Ring” |
| 973 |
Barenholtz & Feldman |
The determination of visual figure and ground in dynamically transforming shapes |
| 974 |
Kovács, Zimmer & Kovács |
Electrophysiological correlates of contour integration in human visual cortex |
| 975 |
Penna, Montesanto, Stara & Dasara |
A neural network model of Gestalt-like visual processing |
| 976 |
Supèr & Lamme |
Neural signals in monkey primary visual cortex that predict direction and latency of saccades |
| 977 |
Purves & Yang |
Statistical basis for the perception of contrast, orientation, spatial frequency and color |
| Faces 3 |
978 |
Bronstad & Langlois |
Image warping does not model variation in facial masculinity |
| 979 |
Nishimura, Maurer & Mondloch |
Sentivitity to the spacing of features in novel objects after learning individuals vs. categories |
| 980 |
Yue, Tjan & Biederman |
Matching complementary faces and blobs in the gabor domain by novices, experts, and an ideal observer |
| 981 |
Davidenko & Ramscar |
The distinctiveness effect reconsidered: Poorer recognition of distinctive face silhouettes |
| 982 |
Olmos & Kingdom |
The role of reflectance and shading in face recognition |
| 983 |
Russell |
Face pigmentation and sex classification |
| 984 |
Adler, Zilberberg & Chockalingam |
Sensitivity to the geometric variability of faces in infants |
| 985 |
Dinon & Boucart |
Effect of contrast on face perception: Application to ophthalmology (AMD patients) |
| 986 |
Isogaya, Matsuzaki & Sato |
The effects of external contour of face on gaze perception |
| 987 |
Pilz, Thornton & Bülthoff |
A visual search advantage for faces learned in motion |
| 988 |
McCabe, Chauvin, Fiset, Arguin & Gosselin |
The use of spatial frequency through time in face identification |
| 3D processing: motion & texture |
989 |
Di Luca & Fantoni |
Interpolation of occluded surfaces in structure from motion |
| 990 |
Fernandez & Farell |
Depth-order violation in structure from motion |
| 991 |
Frankl & Nawrot |
Extra-retinal signals in motion parallax: Support from eye movement asymmetries in strabismus |
| 992 |
Domini, Di Luca & Caudek |
Depth from stereo-motion: Estimating the Intrinsic Constraint Line |
| 993 |
Kuhlmann, Grossberg & Mingolla |
A neural model of 3D shape-from-texture: Multiple-scale filtering, cooperative-competitive grouping, and 3D surface filling-in |
| 994 |
Thaler, Todd & Lindsey |
Phase dependent local energy mediates effects of phase scrambling on shape perception from texture |
| 995 |
Todd & Thaler |
A gradient based heuristic for the perception of 3D shape from texture |
| 996 |
Saunders & Backus |
Perception of slant-from-texture for textures with oriented symmetry |
| 997 |
Shavit, Li & Matin |
Spatial induction of changes in perceived elevation and verticality by global and local orientations of sets of lines |
| Attentional Selection |
998 |
Chakravarthi & Cavanagh |
Temporal properties of the polarity effect in crowding |
| 999 |
Geng & Driver |
Competition between stimuli in opposite visual fields |
| 1000 |
Merritt, Hirshman, Wharton, Devlin, Stangl, Bennett & Hawkins |
Gender differences in selective attention: Evidence from a spatial orienting task |
| 1001 |
Fuller & Carrasco |
Hue-contrast is invariant with attention |
| 1002 |
Chen, Mordkoff & Moore |
Responding to the second of two events: The farther away, the better |
| 1003 |
Zhang & Luck |
Effects of color-based selective attention on feedforward sensory processing |
| 1004 |
Lanagan, Fine, Chen & Moore |
Standing out in a crowd: Item discriminability increases attentional resolution |
| 1005 |
Blaser, Kaldy, Eddy & Pomplun |
Determining salience for complex objects |
| 1006 |
Wiediger & Fournier |
Does response type and stimulus duration influence when compatibility interference occurs? |
| 1007 |
Navalpakkam, Telang & Itti |
Attention can be guided to the relevant feature category |
| 1008 |
Franconeri, Alvarez & Enns |
How many locations can you select at once? |
| 1009 |
Ariga & Yokosawa |
Temporally gradual modulation of attention in the RSVP |
| 1010 |
McCarley, Mounts & Hillimire |
Spatially-mediated attentional interference degrades shape processing |
| 1011 |
Chao & Yang |
Inhibition of novel distractors |
| 1012 |
Olds & Weber |
Object-substitution masking: The identity of the mask does matter! |
| 1013 |
Tombu & Tsotsos |
Attentional inhibitory surrounds in orentation space |
| 1014 |
Thomas, Ambinder, Hsieh, Levinthal, Crowell, Irwin, Kramer, Lleras, Simons & Wang |
Fruitful visual search: Inhibition of return in a virtual foraging task |
| 1015 |
Jefferies & Di Lollo |
Observer expectation as a determinant of inhibition of return: Some limiting factors |
| 1016 |
Schuch & Tipper |
Simulation of inhibition: Do i simulate your stopping? |
| Color Vision 2 |
1017 |
Sakurai & Mullen |
Peripheral chromatic sensitivity for rectified stimuli in each cone-opponent system |
| 1018 |
Johnson, Tucker & Fitzpatrick |
Mapping cone specific activity in primary visual cortex |
| 1019 |
Montesanto, Penna & Tascini |
Non-isometric colour similarity |
| 1020 |
Lin & Chen |
Spatial summation of chromatic information |
| 1021 |
Cardinal & Engel |
Neural bases of surface perception from color |
| 1022 |
Baraas, Foster, Amano & Nascimento |
Dichromatic judgments of surface color under different illuminants on natural scenes |
| 1023 |
Amano, Foster & Nascimento |
Complex effects of test-surface color on surface-color judgments with natural scenes |
| 1024 |
Liu & Wandell |
Contrast perception and discrimination of chromatic temporal modulations |
| 1025 |
Jakobson, Pearson & Robertson |
A colour-specific deficit in visual working memory and imagery |
| 1026 |
Aloimonos & Fermuller |
Chromatic induction and perspective distortion |
| 1027 |
Nakano, Tanabe, Mori, Ikegami & Fujita |
Expansive and contractive size perception with color patches |
| 1028 |
Pereverzeva & Teller |
Simultaneous color contrast in 4 months old infants is revealed by a temporal modulation paradigm |
| Object- and Space- Based Attention |
1029 |
Kim, Grabowecky, Paller & Suzuki |
The different properties of object-based and spatial attention revealed by ssveps |
| 1030 |
Hecht & Vecera |
Object-based curve tracing in the upper and lower visual fields |
| 1031 |
Fournier, Nelson & Wiediger |
Conjunction benefits can occur for dimensions within an object but not between objects |
| 1032 |
Denney & Brown |
Shifting attention into and out of objects: Evaluating the processes underlying the object advantage |
| 1033 |
Blanc & Stoner |
Object-based attention: Interactions between stimulus features |
| 1034 |
Lu, Yakupov, Lozar, Chang, Ernst & Itti |
Feature-based attention is also object-based |
| 1035 |
Niemeier & Stojanoski |
Contributions of feature-based attention to object perception |
| 1036 |
Kravitz & Behrmann |
Object-based attentional selection modulates the spatial gradient surrounding the object |
| 1037 |
Richard, Hollingworth & Vecera |
The spatial distribution of object-based attention |
| 1038 |
Chou & Yeh |
Modulation of object-based and space-based attention by cue validity |
| 1039 |
Owens & Spehar |
Attentional capture by new object sudden-onsets can be modulated by top-down control |
| 1040 |
Reppa & Leek |
Structure-based modulation of inhibition of return: Implications for theories of object-based selection |
| 1041 |
Walther, Serre, Poggio & Koch |
Modeling feature sharing between object detection and top-down attention |
| 1042 |
Wong, Hillstrom & Chai |
What changes to objects disrupt object constancy? |
| 1043 |
Mitroff, Cheries, Scholl & Wynn |
Cohesion as a principle of object persistence in infants and adults |
| 1044 |
Roitman, Brannon & Platt |
Implicit discrimination of visual arrays by number in rhesus macaques |
| Binocular rivalry |
1045 |
Chong & Blake |
Exogenous and endogenous attention influence initial dominance in binocular rivalry |
| 1046 |
Yazdanbakhsh & Grossberg |
Laminar cortical dynamics of binocular rivalry |
| 1047 |
Alais & Parker |
Independent binocular rivalry processes for form and motion |
| 1048 |
Grabowecky & Suzuki |
Sources of long-term speeding in binocular rivalry |
| 1049 |
Buckthought & Wilson |
Interactions between binocular rivalry and depth in plaid patterns |
| 1050 |
Brascamp, Noest & van den Berg |
The third percept in bistable perception |
| Perceptual/Object Learning |
1051 |
Abbey, Pham, Shimozaki & Eckstein |
Contrast effects in rapid learning of a visual detection task |
| 1052 |
Balas & Sinha |
Motion-based orienting, segmenting and tracking in a model of object learning |
| 1053 |
Mednick, Drummond, Arman & Boynton |
The neural correlates of perceptual learning and deterioration: a role for attention? |
| 1054 |
Ben-Shachar, Dougherty, Deutsch, Potanina & Wandell |
The development of visual sensitivity to words in ventral occipito-temporal sulcus |
| 1055 |
Fiser, Roser, Aslin & Gazzaniga |
Right hemisphere processes dominate the initial phase of visual statistical feature-learning |
| 1056 |
Op de Beeck, Baker, Rindler & Kanwisher |
An increased bold response for trained objects in object-selective regions of human visual cortex |
| Motion; form from motion |
1057 |
Gold, Cook, Tadin & Blake |
The efficiency of biological motion perception |
| 1058 |
Troje & Westhoff |
Detection of direction in scrambled motion: a simple “life detector”? |
| 1059 |
Likova & Tyler |
Structure-from-transients: HMT/MST mediates figure/ground segmentation |
| 1060 |
Anstis & Ito |
Background stripes affect apparent speed of rotation |
| 1061 |
Benton & O'Brien |
Fractal rotation stimulus activates human MT/V5 |
| 1062 |
Friedrich & Mamassian |
Measuring motion capture with a Vernier task |
| 1063 |
Kourtzi, Vatakis & Krekelberg |
Global motion from form in the human visual cortex |
| Visual Attention, Learning, and Memory |
1064 |
Green & Bavelier |
Effects of video game playing on visual processing across space |
| 1065 |
Lefebvre, Seitz, Watanabe & Jolicoeur |
Learning blinks during the attentional blink |
| 1066 |
Vogel, McCollough, Fair & Woodman |
Maintaining visual short-term memory representations across new object onsets |
| 1067 |
Turk-Browne, Junge & Scholl |
Attention and automaticity in visual statistical learning |
| 1068 |
Humphreys & Watson |
Visual memory interference with preview search: VSTM and viusal marking |
| 1069 |
Robinson, Manzi & Triesch |
The costs of visual working memory |
| 1070 |
Park, Kim & Chun |
The type of working memory load influences the magnitude of distractor interference in a selective attention task |
