| Eye Movements: Pursuit and Vergence |
1 |
Yang, Zhu, & Hertle |
Version and vergence eye movements in optokinetic nystagmus induced by optic flow |
| 2 |
Berryhill, Chiu, & Hughes |
Following the feeling: Proprioceptive smooth pursuit revisited |
| 3 |
Braun, Mennie, & Gegenfurtner |
Pursuit eye movements to isoluminant targets |
| 4 |
Ponce, Lomber, & Born |
Contributions of visual areas V2 and V3 to the analysis of depth and motion signals guiding smooth eye movements |
| 5 |
Montagnini, Spering, & Masson |
Combining 1D visual motion and 2D predictive signals to control smooth pursuit eye movements |
| 6 |
Matsumiya & Shioiri |
High spatial frequency superiority of motion aftereffect for smooth pursuit eye movements |
| 7 |
Toole & Fogt |
A novel automated method for marking catch-up saccades |
| Face Recognition |
8 |
Russell & Sinha |
Pigmentation is important for recognition of familiar faces |
| 9 |
Dal Martello & Maloney |
Where are kin recognition cues in the face? |
| 10 |
Bülthoff & Newell |
Voices, not arbitrary sounds, prime the recognition of familiar faces |
| 11 |
O'Toole, Phillips, Jiang, Ayyad, Pénard, & Abdi |
Face recognition algorithms surpass humans matching faces in images that vary in illumination |
| 12 |
Roark, Abdi, & O'Toole |
When does an unfamiliar face become familiar? The effect of image type and familiarity on recognition from novel viewing conditions |
| 13 |
Nakato, Kanazawa, & Yamaguchi |
The 3/4 view effect and the rotation information in infants' face recognition |
| 14 |
Nakata & Osada |
Similarities and differences between humans' and Squirrel monkeys' (Saimili sciureus) facial recognition strategies |
| Perceptual Organization: 2D Shape |
15 |
Tani & Sato |
Early processes mediate Café Wall illusion |
| 16 |
Borra, Hooge, & Verstraten |
The Brain knows about the Oblique Effect |
| 17 |
Woloszyn & Sheinberg |
No lateral-vertical asymmetry in the processing of mirror images in the monkey |
| 18 |
Poirier & Wilson |
A neural model of symmetry perception for curved shapes |
| 19 |
Grace, Izard, Shutts, Dehaene, & Spelke |
Sensitivity to geometry in male and female children and adults in the U.S. and in an Amazonian indigene group |
| 20 |
Friedenberg & Liby |
Estimation of three-body center of mass: Effects of size ratio and lightness |
| 21 |
Malloy & Jensen |
Apparent motion, phase relations, and the perception of form |
| 22 |
Kennedy, Orbach, & Loffler |
Shape can bias angle perception: An angle illusion |
| 23 |
Feldman & Singh |
Bayesian estimation of the shape skeleton |
| Working Memory |
24 |
Lin & Sperling |
Visual short-term memory and context memory for grating contrast |
| 25 |
Hollingworth & Sacks |
The updating of object-position binding in visual short-term memory |
| 26 |
Ganel, Gonzalez, Valyear, Culham, Goodale, & Köhler |
The relationship between fMRI adaptation and repetition priming of visually presented objects |
| 27 |
Sussman & Jiang |
Effects of decay and interference on visual working memory for color |
| 28 |
Johnson & Spencer |
A dynamic neural field approach to multi-item visual
working memory and change detection |
| 29 |
Pearson & Jakobson |
Colour-specific deficits in explicit visual working memory: A case study |
| 30 |
Todd, Harrison, & Marois |
Neural dissociation of visual working memory consolidation and maintenance |
| 31 |
Nilsson |
Psychophysical visual memory data and their neural net replications indicate sensory-like activity is released from storage |
| 32 |
McCollough & Vogel |
Control processes in working memory |
| 33 |
Wyble & Bowman |
A neural network account of binding discrete items into working memory using a distributed pool of flexible resources |
| 34 |
Vogel, Ikkai, & Perez |
Do perceptually challenging objects consume more working memory capacity? |
| 35 |
Shen, Makovski, & Jiang |
Short-term visual memory for motion path |
| 36 |
Carlson & Alvarez |
Suboptimal allocation of visual short term memory resources |
| 37 |
Niederhoefer & Blaser |
The functional units of visual working memory: Objects or locations? |
| 38 |
Ezzyat & Olson |
The hippocampus and the fidelity of representations in visual working memory |
| 39 |
Lee, Mozer, & Vecera |
The mechanism of priming of pop-out: Stored short-term memory representation or perceptual level weight changes? |
| 40 |
Ahn, Jeong, & Kim |
Top-down attentional shift in object working memory task: A distinction between 'what' and 'where' in visual working memory still remains uncertain |
| 41 |
Angelone, Beck, Amante, Sikorski, & Materna |
Visuospatial and object working memory in naturalistic scene change detection |
| Binocular Rivalry/Bistability/Awareness |
42 |
Bonneh, Polat, & Tsodyks |
Why do we see binocular rivalry? Evidence from people who see it fused |
| 43 |
Carter, Pettigrew, Hasler, Wallis, & Vollenweider |
Psilocybin slows binocular rivalry switching through serotonin modulation |
| 44 |
Chong & Blake |
Unseen objects influence estimation of average size |
| 45 |
Ferneyhough, Meng, & Tong |
Interactions between binocular rivalry and perceptual filling-in of visual phantoms |
| 46 |
Kang & Blake |
How to enhance the incidence of stimulus rivalry |
| 47 |
Kim, Buckthought, & Wilson |
Dynamical properties of second-order processing in binocular vision and rivalry |
| 48 |
Kimura, Abe, & Goryo |
Visibility modulation of rivalrous color flashes in the flash-suppression paradigm: Stimulus-specific modulation dominates over a wide range of temporal parameters |
| 49 |
Knapen, Paffen, Kanai, & van Ee |
Stimulus flicker alters interocular grouping during binocular rivalry |
| 50 |
Sterzer & Rees |
A neural basis for perceptual memory during binocular rivalry in humans |
| 51 |
Noest, van Ee, & van Wezel |
Visual choice dynamics: Explaining repetition and predicting alternation of bistable percepts driven by stimulus ON/OFF timing |
| 52 |
Mitroff, Sobel, & Gopnik |
Reversing how to think about ambiguous figure reversals: Spontaneous alternating by uninformed observers |
| 53 |
Sundareswara, Kallie, & Schrater |
Perceptual bistability modulated by priming |
| 54 |
Yoshino & Sakaguchi |
Effects of feature changes of faded objects on its reentry to our awareness |
| 55 |
Leh, Mullen, & Ptito |
The involvement of the superior colliculi in hemispherectomized subjects with blindsight |
| Change Detection |
56 |
Simons, Ambinder, Wan, Nevarez, & Caddigan |
Examining the factors that influence change detection |
| 57 |
Moore & Lanagan |
No evidence (so far) of accruing representations of change over time |
| 58 |
Burmester & Wallis |
Capacity limits for the detection of changing visual features |
| 59 |
Taya & Mogi |
The role of attention in change blindness |
| 60 |
Kies & Chubb |
Influence of local context in change detection |
| 61 |
Kempgens, Loffler, & Orbach |
Change detection in patterns depends on pattern shape and element arrangement |
| Oscillations, Correlations, Synchrony |
62 |
Chatterjee, Merwine, & Grzywacz |
Stimulus-dependent response correlations between rabbit retinal ganglion cells |
| 63 |
Ishikane, Gangi, Honda, Usui, & Tachibana |
Visual information coding by synchronized oscillations |
| 64 |
Ebisch, Barnes, Egenolf, Lomber, & Galuske |
Superior colliculus modulates oscillatory activity of neuronal responses in primary visual cortex |
| 65 |
Anderson, Harrison, & Sheinberg |
Neuronal synchrony and visual grouping: A multi-electrode study in monkey IT |
| 66 |
Jermakowicz, Chen, Khaytin, Zhou, Bernard, Bonds, & Casagrande |
Does spike synchrony provide a better code of stimulus angle than average firing rate? |
| 67 |
Bernard, Zhou, & Bonds |
Synchronous activity in cat visual cortex detects structural modifications in natural images |
| 68 |
Zhou, Bernard, & Bonds |
Synchrony modulation in cat visual cortex reflects structure from coherent motion of random dots |
| 69 |
Amano, Arnold, Johnston, & Takeda |
Watching the brain oscillating : A neural correlate of illusory jitter |
| Human Factors |
70 |
Ferwerda & Arditi |
High dynamic range displays and the "blue light hazard" |
| 71 |
Strasburger & Wüstenberg |
Calibrated LCD stimulus presentation for visual psychophysics in fMRI |
| 72 |
Rigutti & Gerbino |
Navigating in a web site: Label-following vs. layout-following strategies |
| 73 |
Sheedy & Gowrisankaran |
Viewing compromised visual stimuli causes dry eye symptoms: Role of the orbicularis muscle |
| 74 |
Huber, Davies, Stringer, & O'Neil |
Station-point violations and their effect on size perception in minimal access surgery |
| 75 |
McLin, Barnes, Novar, Martinsen, & Garcia |
Gabor discrimination and laser disability glare |
| 76 |
DaSilva, Wechsler, McBeath, Sugar, Amazeen, Presson, & Koeneman |
Improvement in upper-extremity motor-function in hemiparetics using robot-assisted repetitive motion therapy with video games |
| Motion and Eye Movements |
77 |
Souman & Freeman |
Phase lags and gain ratios in motion perception during smooth pursuit eye movements |
| 78 |
Freeman |
Pursuit eye movement, motion adaptation and two types of velocity aftereffect |
| 79 |
Spering & Gegenfurtner |
Visual contextual effects on smooth pursuit eye movements |
| 80 |
Sheliga, FitzGibbon, & Miles |
The initial ocular following responses (OFRs) to competing visual motions: Contrast-dependent nonlinear interactions and their dependence on spatial frequency and speed |
| 81 |
Kaminiarz, Rohe, Krekelberg, & Bremmer |
Localization of visual targets during optokinetic eye movements |
| 82 |
Morrone, D'Avossa, Tosetti, & Burr |
Modulation of retinotopy of human MT complex by gaze position |
| Face Perception: Neural Mechanisms |
83 |
Harris & Nakayama |
Face-selective adaptation of the M170 is sensitive to face parts, not face configuration |
| 84 |
Tanaka, Piatt, & Sadr |
The Visual Aha!: Insights into object and face perception using event related potentials |
| 85 |
Fabre-Thorpe, Rousselet, Macé, & Thorpe |
Teasing apart meaningful from meaningless ERP differences in object categorization: A complicated story |
| 86 |
Haxby, Bryan, & Gobbini |
The representation of mammalian faces in human cortex |
| 87 |
Engell, Gobbini, & Haxby |
Distributed representations of face expression and gaze perception in human temporal cortex |
| 88 |
Thomas, Avidan, Jung, & Behrmann |
Disruption in structural connectivity in ventral cortex in congenital prosopagnosia |
| Eye Movements, Brain Activity, and Attention |
89 |
Gersch, Schnitzer, Sanghvi, Dosher, & Kowler |
Attentional enhancement along the path of a sequence of saccades |
| 90 |
Horowitz, Fine, Fencsik, Yurgenson, & Wolfe |
Fixational eye movements do not predict attentional benefits |
| 91 |
Krishna, Falkner, & Goldberg |
Spatiotemporal properties of saccadic inhibition and potential neural correlates in the macaque |
| 92 |
White, Kerzel, & Gegenfurtner |
Facilitation of saccade latency with natural scene backgrounds |
| 93 |
Wallis |
On the spatio-temporal limits of retinal motion compensation, and why they are the undoing of temporal binding |
| 94 |
Wilmer & Nakayama |
A large gender difference in smooth pursuit precision |
| Perceptual Organization |
95 |
Sinha, Ostrovsky, & Meyers |
Parsing visual scenes via dynamic cues |
| 96 |
Palmer & Ghose |
Extremal edges dominate other cues to figure-ground organization |
| 97 |
Trujillo, Peterson, & Allen |
Erp components index unconscious versus conscious perception of familiar shape with figure-ground reversal |
| 98 |
Maertens, Pollmann, & Shapley |
Illusory contours don't pass through the 'blind spot' |
| 99 |
Gerbino, Scomersi, & Fantoni |
Amodal completion enhances the discrimination of Vernier offset |
| 100 |
Fulvio, Singh, & Maloney |
The human visual spline: Interpolation contours between relatable inducers follow quintic polynomials |
| Natural Images and Position Encoding |
101 |
Sharan, Li, & Adelson |
Image statistics for surface reflectance estimation |
| 102 |
Adelson, Tappen, Freeman, & Li |
Learning the statistics of illumination and reflectance |
| 103 |
Ing & Geisler |
Ribbon analysis of contours in natural images |
| 104 |
Rucci, Desbordes, Iovin, & Santini |
Contributions of fixational eye movements to visual discrimination |
| 105 |
Hamker, Zirnsak, Calow, & Lappe |
The perisacadic compression of visual space – what may it have to do with spatial attention? |
| 106 |
Bennett, Taylor, & Sekuler |
Preservation of position-encoding mechanisms across the life span |
| 107 |
Whitney & Bressler |
The precision of position coding in the visual cortex |
| Motion: Cortical Mechanisms |
108 |
Snodderly & Gur |
Evidence for a motion-selective pathway from V1 to the ventral cortical stream for object recognition |
| 109 |
Zaksas, LaMendola, & Pasternak |
Remembered direction modulates responses to visual motion in MT and prefrontal neurons |
| 110 |
Freedman & Assad |
Categorical representation of visual motion direction in posterior parietal cortex area LIP |
| 111 |
Lee, Pesaran, & Andersen |
Self-motion is represented in an eye-centered coordinate frame in SMTd |
| 112 |
Lorenceau, Morel, Caclin, & Tallon-Baudry |
Apparent motion speed dependence on contrast and orientation: Evidence from MEG |
| 113 |
Smith, Wall, Lingnau, & Ashida |
Sensitivity to optic flow in human MT and MST measured with fMRI adaptation |
| 114 |
Thompson & Liu |
Motion discrimination with psychophysically suppressed MT: an fMRI study |
| Spatial Vision I |
115 |
Taylor, Bennett, & Sekuler |
Narrow-band channels optimally sum a broad band of spatial frequency information |
| 116 |
Abbey & Eckstein |
Classification images of bandpass mechanisms across noise spectral density |
| 117 |
Elder & Morgenstern |
Power spectrum classification image analysis reveals localized mechanisms underlying nonlinear detection of narrowband stimuli |
| 118 |
Oruc & Landy |
Letter identification: Evidence for scale dependence but not for fixed channels |
| 119 |
Klein & Tyler |
Gaussian basis functions for fitting the Gabor sector of the Modelfest data |
| Temporal Processing |
120 |
Stockman, Sharpe, Michaelides, Moore, Webster, & Smithson |
Second sight: Vision sustained by a secondary activation of the phototransduction cascade |
| 121 |
Posina, Horwitz, & Albright |
Distinct temporal dynamics of cone-opponent and -nonopponent macaque primary visual cortical neurons |
| 122 |
Ogmen, Breitmeyer, Kafaligonul, Todd, Mardon, & Ziegler |
Temporal aspects of contour and brightness processing in meta- and paracontrast |
| 123 |
Cass & Alais |
Evidence for interacting temporal channels: Spatial determinants |
| 124 |
Motoyoshi |
Temporal freezing of surface properties |
| Attention and Working Memory |
125 |
Kim, Min, Kim, & Won |
Concurrent working memory load can reduce distraction: An fMRI study |
| 126 |
Han & Kim |
Spatial working memory load impairs signal enhancement, not attentional orienting |
| 127 |
Kim & Kim |
Working memory training reduces working memory load effect |
| 128 |
Kim, Kim, & Chun |
Predictive spatial working memory content guides visual search |
| 129 |
Chou & Yeh |
Effects of spatial and non-spatial working memory on location- and object-based attention |
| 130 |
Sobel, Gerrie, Kane, & Poole |
Working memory capacity influences the top-down factors in visual search |
| 131 |
Golomb & Chun |
Working memory load can impair neural processing of unattended information |
| 132 |
Rhode, Baugh, Pearson, Jakobson, & Marotta |
Colour-specific deficits in implicit colour working memory: A visuomotor case study |
| 133 |
Morales & Thompson-Schill |
Rehearsal in visual memory |
| 134 |
Varakin & Levin |
Visual working memory matches do not always attract attention |
| Locomotion and Navigation |
135 |
Cohen, Bruggeman, & Warren |
Combining moving targets and moving obstacles in a locomotion model |
| 136 |
Bruggeman, Rothman, & Warren |
Is obstacle avoidance controlled by perceived distance or time-to-contact? |
| 137 |
Soska & Gilmore |
Optic flow aids in the formation of cognitive maps |
| 138 |
Diaz & Fajen |
Flexible attunement to different optical variables in visually guided action |
| 139 |
Fajen |
Perceptual learning and the visual guidance of braking |
| 140 |
Kalia, Legge, & Giudice |
Learning virtual building layouts: The effects of age on the usefulness of geometric and nongeometric visual information |
| 141 |
Woods, Lichtenstein, Mandel, & Peli |
Collision detection and factors affecting "reality" of a virtual environment |
| 142 |
Warren |
The behavioral dynamics model of locomotor control: Integrating basic behaviors |
| 143 |
Rothman & Warren |
Wormholes in virtual reality and the geometry of cognitive maps |
| 144 |
Zhong, Harrison, & Warren |
The role of topological boundary relations in active navigation |
| 145 |
Owens & Warren |
Intercepting moving targets on foot: Can people learn to anticipate multiple trajectories? |
| 146 |
Wu, Zhao, Liu, Campos, & Sun |
Estimating distance and duration of travel: A possible shared mechanism |
| 147 |
Philbeck & O'Leary |
Path integration precision is increased near familiar destinations |
| 148 |
Seno & Sato |
Temporonasal motion induces stronger vection |
| 149 |
Kitazaki & Hashimoto |
Effects of perspective jitter on vection and visual control of posture are dissociated |
| 150 |
Lee & Spelke |
Children's use of extended three-dimensional surfaces for reorientation |
| Perceptual Learning |
151 |
Kim, Seitz, & Shams |
Sound aids perceptual learning |
| 152 |
Shams, Seitz, & van Wassenhove |
Audio-visual statistical learning |
| 153 |
Hussain, Bennett, & Sekuler |
Face-inversion effects flex with perceptual learning |
| 154 |
Peterson & Eckstein |
Perceptual learning of discriminating features for facial recognition |
| 155 |
Chu, Lu, & Dosher |
Effects of perceptual learning on the temporal dynamics of perceptual decision |
| 156 |
Eckstein, Pham, Abbey, & Zhang |
Learning to discount noise |
| 157 |
Matthews, Kurosawa, & Strong |
Hastening orientation sensitivity |
| 158 |
Seitz, Náñez, Holloway, & Watanabe |
Perceptual learning of motion leads to faster-flicker perception |
| 159 |
Vavassis & von Grünau |
Practice-induced improvements for target detection in rapidly presented visual search displays is temporal-context-dependent |
| 160 |
Heckman & Engel |
Perceptual learning of contrast detection is color selective |
| 161 |
Holloway, Tsushima, Náñez, Watanabe, & Seitz |
Two cases of a requirement of feedback for perceptual learning |
| 162 |
Jeter, Dosher, & Lu |
Specificity of perceptual learning for difficult tasks during simultaneous training |
| 163 |
Liu, Lu, Huang, & Zhou |
Motion perceptual learning: Only task-relevant stimulus information is learned |
| 164 |
Mednick, Serences, Boynton, & Awh |
Sleep-dependent perceptual learning with and without distractors |
| 165 |
Nishina, Seitz, Kawato, & Watanabe |
The spatio-temporal window of task-irrelevant perceptual learning |
| 166 |
Padilla & Grzywacz |
Is statistical learning theory applicable to the human brain? |
| 167 |
Petrov |
Bayesian method for repeated threshold estimation |
| 168 |
Li, Provost, Sung, Nguyen, Young, Hoenig, & Levi |
The limits of perceptual learning in previously untreated amblyopia: An intensive case study |
| 169 |
Haijiang & Backus |
Temporal aspects of cue recruitment in visual perception |
| Multi-Sensory Processing |
170 |
Davis, Scott, Hailston, Pair, & Hodges |
Ambient sounds can enhance visual perception and memory performance in virtual environments |
| 171 |
Alais & Weston |
Temporal ventriloquism: Perceptual shifts in temporal position and improved audiovisual precision predicted by maximum likelihood estimation |
| 172 |
Andersen & Mamassian |
Audiovisual interactions in signal detection |
| 173 |
Beer & Watanabe |
Modulation of visual perceptual learning by sounds |
| 174 |
Heller, Gilman, Sripada, & Helman |
Auditory-visual interactions in the judgment of a ball's speed |
| 175 |
Watkins, Shams, & Rees |
Effects of concurrent auditory stimulation on human visual cortex |
| 176 |
Wozny & Shams |
Integration and segregation of visual-tactile-auditory information is Bayes-optimal |
| 177 |
James, Kilgour, Servos, Kitada, Huh, & Lederman |
Haptic exploration of facemasks recruits left fusiform gyrus |
| 178 |
Giudice & Loomis |
Orientation specificity with vision and touch: Map learning, haptic updating, and functional equivalence |
| 179 |
Helbig, Ricciardi, Pietrini, & Ernst |
Integration of shape information from vision and touch: Optimal perception and neural correlates |
| 180 |
Wu, Klatzky, Shelton, & Stetten |
Interaction of visual and haptic cues in the image-based perception of depth |
| 181 |
Frissen & Ernst |
Visual bias of perceived tactile location |
| 182 |
Batson, Beer, & Watanabe |
Task-irrelevant perceptual learning of crossmodal links in exogenous covert orienting |
| 183 |
Dyde, Jenkin, Jenkin, Zacher, & Harris |
The role of visual background orientation on the perceptual upright during microgravity |
| 184 |
Gingras, Rowland, & Stein |
Behavioral assessment of unisensory and multisensory integration |
| 185 |
Jenkin, Zacher, & Harris |
Does the levitation illusion depend on the view seen or the scene viewed? |
| 186 |
Jordan, MacLean, & Brannon |
Monkeys match sequentially presented sets with simultaneously presented arrays based on numerosity |
| 187 |
Latinus & Taylor |
Effects of attention on face and voice processing |
| 188 |
MacNeilage, Levitan, & Banks |
Relative weights of static and dynamic visual cues in the perception of body roll |
| 189 |
McCormick & Mamassian |
What does the illusory-flash look like? |
| 190 |
Seizova-Cajic & Sachtler |
Visual aftereffects of proprioceptive stimulation not due to proprioceptive adaptation |
| Spatial Vision: Mechanisms and Texture |
191 |
Georgeson |
Bars & Edges: A multi-scale Gaussian derivative model for feature coding in human vision |
| 192 |
Jeon, Lu, & Dosher |
Extending observer models for more difficult identification and discrimination |
| 193 |
Olzak, Wagge, & Thomas |
Signal detection analyses of an uncertainty discrimination paradigm |
| 194 |
Wichmann & Henning |
The pedestal effect is caused by off-frequency looking, not nonlinear transduction or contrast gain-control |
| 195 |
Sally & Gurnsey |
Orientation discrimination threshold-as-a-function-of-size curves shift more dramatically with increased stimulus contrast at 0 than 10 degrees in the temporal visual field |
| 196 |
Govenlock, Taylor, Sekuler, & Bennett |
Orientation tuning channels in old and young observers |
| 197 |
Legault, Allard, & Faubert |
Curvature perception in aging |
| 198 |
Baron & Pelli |
Crowding counting |
| 199 |
Kramer & Olzak |
Collinearity and surround size effects on spatial discrimination tasks |
| 200 |
Meese & Holmes |
Cross-orientation suppression is proportional to the square-root of speed for flickering Gabor stimuli |
| 201 |
Chubb, Solomon, & Morgan |
Evidence for plaid-grabbers |
| 202 |
McKee, Wade, Petrov, & Norcia |
The neural correlates of human surround suppression |
| 203 |
Meigen & Hottenroth |
Lateral interaction mechanisms in texture segregation can be studied with a two-frequency VEP method |
| 204 |
Conte, Ashurova, Ponticello, Kobylarz, Labar, & Victor |
Changes in VEP indices of cortical lateral interactions with epilepsy treatment |
| 205 |
Victor, Ashurova, Chubb, & Conte |
Isodiscrimination contours in a three-parameter texture space |
| 206 |
Maddess, Nagai, & Victor |
Multi-level isotrigon textures |
| 207 |
Maruya, Nakajima, & Sato |
Processing time of second-order contour formation |
| 208 |
Sezikeye & Gurnsey |
Effects of variability and size on texture discrimination asymmetry |
| 209 |
Baker, Mortin, Prins, Kingdom, & Dumoulin |
Visual cortex responses to different texture-defined boundaries: An fMRI study |
| 210 |
Hess & Hansen |
How important is spatial phase in texture segmentation and contour integration? |
| Attention: Selection and Modulation |
211 |
Berg, Boehnke, Marino, Baldi, Munoz, & Itti |
Characterizing surprise in humans and monkeys |
| 212 |
Brauer & Dannemiller |
Salience effects on bilateral cuing |
| 213 |
Breitmeyer, Koç, & Öğmen |
Priming and masking interactions shape the transient component of focal attention |
| 214 |
Min & Kim |
Negative priming in pure perceptual-based sequence learning |
| 215 |
Fehd & Seiffert |
Attention strikes back: Counteracting the effects of adaptation with attention |
| 216 |
Highsmith, Stoebling, Gulla, & Crognale |
Does attention modulate chromatic VEP responses? |
| 217 |
Nishimura & Yokosawa |
Cueing of the stimulus location in polarity correspondence effect |
| 218 |
Pechenkova |
Measuring accommodation of visual attention: Titchener's "attention-wave" reconsidered? |
| 219 |
Tseng, Papathomas, & Vidnyanszky |
Learning-induced sensitization for motion directions is modulated by attention |
| 220 |
von Grünau, Galera, Panagopoulos, & Cavallet |
Exogenous attention distorts visual space and speeds up processing: Effects on apparent size |
| 221 |
Wong, Hillstrom, & Peterson |
Morphed objects do not capture the eyes |
| 222 |
Wong-Drew, Chubb, & Sperling |
Attentional filtering of dot intensities in centroid estimations |
| 223 |
Yeshurun |
Transient attention and selective adaptation to high and low spatial frequencies |
| 224 |
Montagna & Carrasco |
Transient covert attention increases the perceived rate of flicker |
| 225 |
Rodriguez, Gobell, Fuller, & Carrasco |
Apparent contrast differs across the vertical meridian of the visual field: Visual and attentional factors |
| Color |
226 |
Kuyk, Garcia, Brockmeier, Gorsche, & Martinsen |
Measuring the impact of laser eye protection on color vision |
| 227 |
Zwick, Edsall, Hare, & Ness |
Utilization of the Crawford transformation in evaluation of spectral background efficiency of solid state light sources |
| 228 |
Mizokami, Webster, & Webster |
Characteristic variations in the color statistics of natural scenes |
| 229 |
Huang, Mullen, & Hess |
Flank facilitation for isoluminant chromatic stimuli |
| 230 |
Naito, Hirano, & Kikuchi |
Loss of position perception and size constancy for equiluminant counterphase flickering color stimuli |
| 231 |
Wachtler & Klauke |
The "chromatic tilt" effect: Hue changes induced by a chromatic surround |
| 232 |
Sakurai & Mullen |
Cone weights for the cone opponent detection mechanisms in human peripheral vision |
| 233 |
Xu & Fine |
Are color-selective neurons representing structure? |
| 234 |
Nagai & Uchikawa |
Comparison between figure segregation and color discrimination thresholds for multi-colored texture stimuli |
| 235 |
Miyahara & Hwang |
Misreading patterns of Ishihara plates by normal trichromats |
| 236 |
Brenner, Granzier, & Smeets |
Variability in symmetric and asymmetric colour matching |
| 237 |
Michna, Mullen, & Yoshizawa |
Temporal luminance artifacts in chromatic motion are specific to L/M cone systems |
| 238 |
D'Antona & Shevell |
Distortion products in chromatic induction: Nulling of induced temporal frequencies not present in the stimulus |
| 239 |
Hsieh & Tse |
Illusory color mixing upon perceptual filling-in does not result in 'forbidden colors' and reveals cortical processing |
| 240 |
Logvinenko |
Partial colour matching: A new method to measure unique hues |
| 241 |
Monnier & Troup |
Classical definitions of chromatic induction are inadequate for induction with S-cone patterned backgrounds |
| 242 |
Uchikawa, Kawahara, & Segawa |
Chromatic induction of moving dots in a motion-defined layer |
| 243 |
Beattie & Logvinenko |
Hue scaling without hue naming |
| 244 |
Boi & Pinna |
The colored flashing spots illusion |
| 245 |
Bostic, Robilotto, & Zaidi |
Reflectance identification of real colored objects across real illuminants |
| 246 |
Bloj & Ruppertsberg |
The role of mutual illumination in gradient formation |
| 247 |
Hurlbert & Ling |
Color constancy of chromatically textured surfaces |
| 248 |
Papathomas, Su, Jain, & Uzochukwu |
The saliency of luminance and color (diagnostic and anti-diagnostic) in images |
| 249 |
Gerhard & Maloney |
Can semantic information prime surface color judgments? |
| 250 |
Ling & Hurlbert |
An extended model for color preference |
| 251 |
Simmons |
The association of colours with emotions: A systematic approach |
| 252 |
Lindsey & Brown |
Color name evolution in the world color survey: A K-means analysis |
| Surfaces and Shape |
253 |
Chen & Chen |
Cortical activation for 3D shapes constructed from different depth cues |
| 254 |
Durand, Nelissen, Vanduffel, Todd, Norman, & Orban |
Primate ips areas involved in visual 3D shape processing |
| 255 |
Kuhlmann, Grossberg, & Mingolla |
3D surface representations derived from texture gradients: Filtering, grouping and filling-in |
| 256 |
Li, Tzen, Yadgarova, & Zaidi |
3D curvature aftereffects from illusory orientation flows |
| 257 |
Saunders & Backus |
Perceived depth from linear perspective as a function of image size |
| 258 |
Schofield, Rock, Hesse, Georgeson, & Yates |
The role of texture amplitude in shape from shading |
| 259 |
van Doorn, Koenderink, & Pont |
Perception of illuminance flow in the case of anisotropic rough surfaces |
| 260 |
Koenderink, Pont, & van Doorn |
A new twist to the "shading cue" |
| 261 |
Gerardin, de Montalembert, & Mamassian |
Polo mint shading |
| 262 |
Ho, Maloney, & Landy |
The effect of viewpoint on visually perceived surface roughness in binocularly viewed scenes |
| 263 |
Murray |
Local 3D shape and reflectance statistics of natural surfaces |
| 264 |
Vishwanath & Banks |
How viewing distance and object size affect judgments of shape in pictures |
| 265 |
Freeman & Driver |
Selection of specific subjective states via contextual disambiguation in structure-from-motion |
| 266 |
Banks & Girshick |
Partial invariance for 3D layout in pictures |
| 267 |
Khalil & McBeath |
Canonical representaion: An examination of preferences for viewing and depicting 3-dimensional objects |
| 268 |
Li & Pizlo |
Is viewer-centered representation necessary for 3D shape perception? |
| 269 |
Simpson, Shahani, & Manahilov |
Classification objects |
| 270 |
Mitsudo |
Stereoscopic structure seen in flat patterns |
| 271 |
Rogers |
Failures of stereoscopic depth constancy: Fact or artefact? |
| Face Perception |
272 |
Goffaux & Rossion |
Face inversion disproportionately impairs the perception of vertical but not horizontal relations between features |
| 273 |
Fiset, Blais, Gosselin, & Schyns |
Effective frequency tuning of three face categorization tasks |
| 274 |
Intriligator & Kaltreider |
Faces and familiarity: Not all fame is the same |
| 275 |
Steinmetz & DaSilva |
Categorizing blurred images |
| 276 |
Gaspar, Bennett, & Sekuler |
Orientation congruence judgments in faces & words |
| 277 |
Anderson & Wilson |
Behavioural tuning of face-selective neural populations |
| 278 |
Curby & Gauthier |
The timecourse of expert and novice visual object encoding |
| 279 |
Deaner, Shepherd, Ristic, & Platt |
Familiarity accentuates gaze-following in women but not men |
| 280 |
Dunham & Banaji |
The “angry = black” effect across the lifespan |
| 281 |
Isogaya, Maruya, Nakajima, Tani, & Sato |
A self-range defined by gaze perception affected by characteristics of personality |
| 282 |
Simion & Shimojo |
A systematic investigation of the gaze manipulation effect |
| 283 |
Rhodes, Maloney, Turner, & Ewing |
Is the average face special? |
| 284 |
Borrmann, Furtado, & Chaudhuri |
Attentional processes involved in facial attention capture |
| 285 |
Habak, Anderson, & Wilson |
Perceived head orientation is affected by the dynamic rotation of neighboring faces |
| 286 |
Shutts, Kinzler, & Spelke |
An ambiguous-race illusion in children's face memory |
| Visual Development |
287 |
Bosworth, Hinga, Robbins, & Dobkins |
Longitudinal study of chromatic and luminance contrast sensitivity in full-term and pre-term infants |
| 288 |
Calvert, Bradnam, Manahilov, McCulloch, Hamilton, & Dutton |
VEP measures of contrast sensitivity in infants and children from 2 months- 15 years of age |
| 289 |
Skoczenski |
Infant vernier acuity improves at low luminance |
| 290 |
Shirai, Kanazawa, & Yamaguchi |
Early development of velocity sensitivity to rotational motion |
| 291 |
Armstrong, Lewis, & Maurer |
Temporal frequency matters: Sensitivity to second-order stimuli in 5-year-olds and adults |
| 292 |
Kaldy, Blaser, & Kibbe |
Detection vs. Saliance of color and motion-defiend stimuli in 6-month-old infants |
| 293 |
Nawrot & Nawrot |
The development of depth from motion parallax in infancy |
| 294 |
Palomares, Gupta, Landau, & Egeth |
Visuospatial interpolation within illusory contours: Evidence from Williams Syndrome and normal children |
| 295 |
Adams, Drover, Penney, Earle, & Courage |
New developments in the evolution of an efficient psychophysical test of spatial contrast sensitivity for pediatric patients |
| Attention: Divided Attention and Inattention |
296 |
Baldwin, Trolka, Carson, & Rossi |
The effect of perceived depth on object substitution masking |
| 297 |
Carmel, Rees, & Lavie |
Behavioral "baseline shift" effects of perceptual load |
| 298 |
Cheries, Wynn, & Scholl |
Interrupting infants' persisting object representations: An object-based limit? |
| 299 |
Choi & Scholl |
Blindness to swapping features in simple dynamic events |
| 300 |
Scholte, Mulckhuyse, Tankink, & Lamme |
Attention can operate independently of awareness |
| 301 |
Libedinsky & Livingstone |
Multi-level suppression during Motion-Induced Blindness |
| 302 |
Shomstein, Behrmann, & Kimchi |
Neglected stimuli influence perception |
| 303 |
Chu & Edelman |
Diminishing attentional capture by attentional set |
| 304 |
Feeney & Dobkins |
Attention effects on motion processing are larger in the left vs. the right visual field |
| 305 |
Ghorashi, Jefferies, & Enns |
Exogenous reconfiguration of the input filter: When it happens and when it does not |
| 306 |
Reddy, Reddy, Perona, & Koch |
Face identification in the near-absence of spatial attention |
| 307 |
Segawa, Kobayashi, & Uchikawa |
Effects of visual attention on depth discrimination in the peripheral visual field |
| 308 |
Stojanoski & Niemeier |
Components of feature-based attention for object perception |
| 309 |
Tsushima & Watanabe |
Sub-threshold task-irrelevant signals disrupt task performance more severely than supra-threshold signals |
| 310 |
Walther, Fei-Fei, & Koch |
Measuring the cost of deploying top-down visual attention |
| 311 |
Yoshida & Cavanagh |
Object substitution masking on the fly |
| Object Recognition I |
312 |
Andresen & Grill-Spector |
View sensitivity of object representations in human object-selective visual cortex |
| 313 |
Bennett & Vuong |
A stereo advantage in generalizing over changes in viewpoint on object recognition tasks |
| 314 |
Chuang, Vuong, Thornton, & Buelthoff |
Role of familiar object motion in recognising objects across viewpoints |
| 315 |
Fazl, Grossberg, & Mingolla |
View-invariant object category learning: How spatial and object attention are coordinated using surface-based attentional shrouds |
| 316 |
Mou, Hayward, Zhao, Zhou, & Owen |
Spatial updating during locomotion does not eliminate viewpoint-dependent visual object processing |
| 317 |
Niimi & Yokosawa |
Recognizing orientation of depth-rotated familiar objects |
| 318 |
Balas & Sinha |
Learning about objects in motion: Better generalization and sensitivity through temporal association |
| 319 |
Peissig, Vuong, Vettel, & Tarr |
Does contrast reversal affect the recognition of common objects? |
| 320 |
Nederhouser, Yue, & Biederman |
Predicting psychophysical similarity of complex shapes from measures of physical similarity |
| 321 |
Christensen & Todd |
What image measures are best correlated with the discriminability of 3D objects? |
| 322 |
Schwartz |
Attneave's Cat revisited: Points of high curvature are not important for shape recognition |
| 323 |
McEntire & Schwartz |
Curvature is encoded stronger than it is perceived |
| 324 |
Harris & Miniussi |
Effects of right parietal TMS on object recognition |
| Perceptual Organization: Contours |
325 |
Richards, Bennett, & Sekuler |
The effects of task switching on age-related differences in shape perception |
| 326 |
Johnson & Soska |
Development of 3D object completion in infancy |
| 327 |
Baker, Tse, Gerhardstein, & Adler |
Six-month-old infants' ability to detect contours |
| 328 |
Tse & Gerhardstein |
Contour detection in young human infants |
| 329 |
Dannemiller & Lunsford |
Element grouping with parabolic contours |
| 330 |
Dillenburger & Wehrhahn |
Real line masks “close the gap” in abutting line type illusory contour processing |
| 331 |
Gu, Dillenburger, & Roe |
A novel dynamically induced 'pure illusory contour' |
| 332 |
Ni, Chen, & Andersen |
Illusory contours formed by temporal interocular unmatched features |
| 333 |
Unuma, Hasegawa, & Kellman |
