| 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 |
