| Face Perception: Experience and Context |
1 |
Yovel & Bartal |
View-invariant representation of unfamiliar faces in the fusiform face area |
| 2 |
Andrews & Ewbank |
fMR-adaptation reveals a view-invariant representation for familiar faces in the fusiform face area |
| 3 |
Ishibashi & Kita |
Our own faces: perceiving fluctuating asymmetry in the highly familiar objects |
| 4 |
Pilz, Bülthoff, & Vuong |
The importance of spatial frequency and familiarity in face recognition |
| 5 |
Armann & Buelthoff |
Sex matters when you ask the right question: What affects eye movements in face comparison tasks? |
| 6 |
Bülthoff & Vuong |
Influence of encoding context on face recognition |
| 7 |
Michel, Rossion, Hayward, Buelthoff, & Vuong |
The role of surface and shape information in the other-race face effect |
| 8 |
Chiao & Franconeri |
Women, but not men, prefer to fixate on the right side of a face |
| 9 |
Elms, Mondloch, & Maurer |
Jane and Ling: Holistic processing and sensitivity to the spacing of features in own- versus other-race faces |
| 10 |
Fiset, Wagar, Tanaka, Gosselin, & Bub |
The face of race: Revealing the visual prototype of Black and White faces in Caucasian subjects |
| 11 |
Ng, Boynton, & Fine |
Face adaptation does not improve perceptual salience |
| 12 |
Nakata & Osada |
Squirrel monkeys' (Saimili sciureus) peculiar facial recognition in the discrimination between own and other species |
| 13 |
Bridge, Li, Tsao, & Chiao |
Universality and cultural specificity in social dominance perception: Effects of gender and culture on facial judgments |
| 14 |
Bowman & Chiao |
What drives the political gender gap?: The role of gender on facial judgments of politicians |
| 15 |
Sy & Giesbrecht |
Who’s looking at you? Gender and familiarity modulate gaze cueing |
| 16 |
O'Brien & Raymond |
Associating reward and loss with faces: Effects on rapid face recognition |
| 17 |
Isogaya, Maruya, Nakajima, Tani, & Sato |
Self-range defined by gaze perception is robust against the size and viewing distance variations |
| 18 |
Otsuka, Kanazawa, Yamaguchi, Abdi, & O'Toole |
The development of face discrimination skill in infants |
| 19 |
Nakato, Otsuka, Midorikawa, Yamaguchi, & Kakigi |
Infants' brain activity on perception of different view faces using near-infrared spectroscopy |
| Eye Movements: Cognitive I |
20 |
Savina, Bergeron, & Guitton |
Effect of training to an area-cue on human saccadic eye movements |
| 21 |
Poletti & Rucci |
Dependence of fixational saccades on the visual task and image fading conditions |
| 22 |
Tanner, Fleming, & Bülthoff |
Eye movements for active learning of objects |
| 23 |
Dalrymple, Bischof, Cameron, Barton, & Kingstone |
Inefficient eye movements correlate with difficulties in perceiving global stimuli in Balint's syndrome |
| 24 |
Heisz & Shore |
More efficient scanning for familiar faces |
| 25 |
Pospisil & Rutan |
Gaze duration differences during a complex scene color preference test occur based on identical vs. dissimilar scenes |
| 26 |
Schirillo |
Mondrian, eye movements, and the oblique effect |
| 27 |
Pelz, Rothkopf, & DeAngelis |
Task dependence of space-time statistics at point of gaze revealed by eye tracking in natural wooded environmen |
| 28 |
Wismeijer, van Ee, & Erkelens |
Influence of perceived depth in a reverse perspective stimulus on vergence |
| 29 |
Rothkopf & Ballard |
Relating contrast statistics at fixation location to navigational control law |
| 30 |
Thorpe, Crouzet, & Kirchner |
Saliency maps and ultra-rapid choice saccade tasks |
| 31 |
Tse, Baker, Adler, & Gerhardstein |
The role of awareness in saccadic conditioning |
| 32 |
Madelain, Champrenaut, & Chauvin |
Control of sensorimotor variability |
| 2D Motion I |
33 |
Apthorp, Alais, & Wenderoth |
Motion streaks improve fine direction discrimination |
| 34 |
Pashkam & Cavanagh |
Effect of motion smear on perceived speed in low luminance |
| 35 |
Bhavaraju & Mingolla |
Speed perception across variations in spatiotemporal frequencies in apparent motion stimuli |
| 36 |
Ruiz-Ruiz & Martinez-Trujillo |
Frames of reference for perceiving motion direction in the human visual system |
| 37 |
Greenwood & Edwards |
Transparent-motion detection requires bimodal population activity |
| 38 |
Armstrong, Lewis, & Maurer |
The development of sensitivity to first- and second-order pattern versus motion |
| 39 |
Disch & De Valois |
Effects of flicker on perceived object velocity |
| 40 |
Yamada, Yamaguchi, & Miura |
Time-to-passage judgments reflect naive physics: The cases of representational gravity and friction |
| Perceptual Learning I |
41 |
Li, Polat, & Bavelier |
Action video game playing alters early visual processing |
| 42 |
Green, Pouget, & Bavelier |
Action videogame playing improves bayesian inference for perceptual decision-making |
| 43 |
Isola, Turk-Browne, & Scholl |
Multidimensional visual statistical learning |
| 44 |
Nishina, Seitz, Kawato, & Watanabe |
Subliminal visual feature is learned better when spatially closer to attended task |
| 45 |
Yotsumoto, Watanabe, & Sasaki |
While V1 activity enhancement that occurs immediately after PL training is nullified due to consolidation, the performance enhancement sustains |
| 46 |
Wenger, Kapelewski, & Eroh |
Tracking changes in cortical responses as a function of perceptual practice |
| 47 |
Ni, Watanabe, & Andersen |
The effect of age on perceptual learning of sub-threshold stimuli |
| 48 |
Gerván & Kovács |
Sleep dependent learning in contour integration |
| 49 |
Giordano, Carrasco, & Rosenbaum |
Covert attention strengthens, speeds and maintains perceptual learning |
| 50 |
Sulman & Sanocki |
Can stimulus-induced affective states influence the rate of PL? |
| Rivalry and Bi-stability I |
51 |
Kimura, Abe, & Goryo |
Attenuation of the pupillary response during interocular suppression |
| 52 |
Knapen, Pearson, Blake, & van Ee |
Increase of perceived speed accompanying onset of interocular suppression |
| 53 |
van Dam, Mulder, Noest, Brascamp, van den Berg, & van Ee |
Sequential dependency in percept durations for binocular rivalry |
| 54 |
van Boxtel, Knapen, van Ee, & Erkelens |
Identical rivalry dynamics for monocular, stimulus and binocular rivalry |
| 55 |
Norman, Norman, Pattison, Taylor, & Goforth |
Aging and the depth of binocular rivalry suppression |
| 56 |
Paffen, Naber, & Verstraten |
Predicting the spatial origin of a dominance wave in binocular rivalry |
| 57 |
Pearson, Clifford, & Tong |
Perceptual and mnemonic contents of mental imagery revealed by binocular rivalry |
| 58 |
Silver & Logothetis |
Temporal frequency and contrast tagging bias the type of competition in interocular switch rivalry |
| 59 |
Su, Ooi, & He |
The speed and spreading of binocular rivalry dominance from boundary contours |
| 60 |
Van Bogaert, Ooi, & He |
Illusory boundary contours affect binocular rivalry and depth perception |
| 61 |
Xu, He, & Ooi |
The roles of boundary contour and stimulus onset asynchrony in triggering binocular rivalry alternation |
| 62 |
Wallis & Arnold |
Staying Focussed: The function of suppression during binocular rivalry? |
| 63 |
Winterbottom, Patterson, & Pierce |
Binocular rivalry and head-worn displays |
| 64 |
Yang, Zald, & Blake |
Processing of fearful faces outside of awareness |
| 3D Perception: Cue Integration |
65 |
Haijiang & Backus |
Newly recruited cue trades against pre-existing cues during the construction of visual appearance |
| 66 |
Backus |
Bayesian model of cue combination for ambiguous stimuli |
| 67 |
Burge, Girshick, & Banks |
Visuo-haptic adaptation: the role of relative reliability |
| 68 |
Girshick, Burge, & Banks |
Bayesian cue combination: coupling of disparity-texture information compared to coupling of visual-haptic information |
| 69 |
Greenwald & Knill |
Grasping for cues: Visual cue integration for object manipulation |
| 70 |
Ishii, Todo, & Yamashita |
Manual control is effective in disambiguating in kinetic depth effect |
| 71 |
Gardner & Palmer |
Joint effects of height-in-the-picture-plane and distance-relative-to-the-horizon in pictorial depth perception |
| 72 |
McCormack, Lowe, & Deng |
Dynamics of registered convergence |
| 73 |
van der Kooij & te Pas |
Curvature contrast occurs after Cue combination |
| Early Visual Processing: Receptive Fields |
74 |
Lu & Roe |
Response to motion and motion boundaries in monkey V2 |
| Cortical Receptive Fields and Perception |
75 |
Meirovithz, Bonneh, Werner-Reiss, Ayzenshtat, Saban, & Slovin |
Voltage-sensitive dye imaging of collinear patterns in the visual cortex of a behaving monkey |
| 76 |
Tong, Zhang, Zheng, Smith III, & Chino |
TimeCourse of surround suppression in V2 neurons of Macaque monkeys |
| 77 |
Zhang, Zheng, Smith, & Chino |
Mature transient responses of V2 neurons in 2-Week-Old infant monkeys |
| 78 |
Kaskan, Baldwin, Zhang, Chino, & Kaas |
The development of local connections in V1 and V2 of macaque monkeys |
| 79 |
Kay, Naselaris, & Gallant |
Estimation of voxel receptive fields in human visual cortex using natural images |
| 80 |
Schumacher & Olman |
BOLD fMRI response to local neural inhibition |
| 81 |
Masquelier, Serre, Thorpe, & Poggio |
Learning simple and complex cells-like receptive fields from natural images: a plausibility proof |
| 82 |
Lui, Dobiecki, Bourne, & Rosa |
Responses of single neurones in the middle temporal area (MT) to kinetic contours: implications for understanding the physiological basis of form cue invariance |
| Perceptual Learning II |
83 |
Bridgeman |
A test of the sensorimotor theory of visual calibration |
| 84 |
Jeter, Dosher, & Liu |
Transfer (vs. specificity) following different amounts of perceptual learning in tasks differing in stimulus orientation and position |
| 85 |
Kim, Seitz, & Watanabe |
Effect of reward on perceptual learning |
| 86 |
Sasaki, Yotsumoto, Shimojo, & Watanabe |
Brain activity related to consolidation of perceptual learning during sleep |
| 87 |
Yu, Klein, & Levi |
Location specificity in perceptual learning: A revisit |
| 88 |
Carrasco, Giordano, & Looser |
Transient attention potentiates perceptual learning |
| 3D Perception |
89 |
Hu & Knill |
Kinesthetic feedback helps disambiguate 3D structure-from-motion |
| 90 |
Di Luca & Ernst |
Integration of alternating cues to slant |
| 91 |
Balas & Sinha |
Does the visual system extract "keyframes" from dynamic object sequences? |
| 92 |
Ernst, Di Luca, & Knill |
How long does it take to adjust a weight? |
| 93 |
MacKenzie, Murray, & Wilcox |
Perceived curvature in depth: a test of cue combination models using motion and binocular disparity |
| 94 |
Li & Zaidi |
3-D curvature aftereffects invariant to texture pattern |
| Global Motion and Motion Integration |
95 |
Tailby, Majaj, & Movshon |
Binocular integration of pattern motion signals by MT neurons and by human observers |
| 96 |
Majaj, Tailby, & Movshon |
Motion opponency in area MT of the macaque is mostly monocular |
| 97 |
Tadin, Grdinovac, Hubert-Wallander, & Blake |
Both simple and choice reaction times reveal suppressive center-surround interactions in motion perception |
| 98 |
Edwards |
Interaction of the On and Off pathways in motion processing with motion-defined-form signals |
| 99 |
Spering & Gegenfurtner |
Contrast and assimilation in visual motion processing for perception and smooth pursuit eye movements |
| 100 |
Royden & Holloway |
The effect of object speed and angle on the perceived rigidity of an optic flow field |
| 101 |
MacNeilage, Butler, Buelthoff, & Banks |
Disambiguation of optic flow with vestibular signals |
| The Many Functions of the Ventral Stream |
102 |
Appelbaum, Vildavski, Pettet, Wade, & Norcia |
Neural dynamics of visual scene segmentation |
| 103 |
Behrmann & Manchin |
Object recognition in ventral temporal cortex is category-graded rather than specific: Neuropsychological evidence |
| 104 |
Tootell, Devaney, Postelnicu, & Ungerleider |
Cortical fMRI maps in response to 3D morphs between head and house |
| 105 |
Singer & Sheinberg |
Joint object and motion selectivity in the temporal cortex |
| 106 |
Meyers, Hung, Freedman, Miller, & Kreiman |
Decoding of ITC cell activity closely predicts human visual similarity judgments |
| 107 |
Rajimehr, Vanduffel, & Tootell |
Retinotopy versus category specificity throughout primate cerebral cortex |
| 108 |
Rouw & Scholte |
Increased structural connectivity in Grapheme-Color Synesthesia |
| Perceptual Organization: Contours I |
109 |
Anderson, Cass, & O'Vari |
Non-Bayesian mechanisms of contour synthesis |
| 110 |
Maertens & Shapley |
Local determinants of contour interpolation |
| 111 |
Fulvio, Singh, & Maloney |
Breakdown of contour interpolation: Testing a multiple-contours hypothesis |
| 112 |
McMains & Kastner |
Illusory contour formation modulates competitive interactions in human extrastriate cortex |
| 113 |
May & Hess |
Ladder contours are undetectable in the periphery |
| 114 |
Horsager & Fine |
Evidence for synchrony using direct electrical stimulation of the human retina |
| Perception and Action I |
115 |
Baldauf & Deubel |
Visual selection of multiple goal positions before rapid hand movement sequences |
| 116 |
Franchak & Adolph |
Perceiving changing affordances for action: Pregnant women walking through doorways |
| 117 |
Wilkie, Robertshaw, & Wann |
Steering performance is influenced by road width, road curvature and gaze behaviour |
| 118 |
McBeath, Sugar, Paranjape, Dolgov, & Wang |
Human and robot ball catching on a Hill: Is the control geometry on the level or atilt? |
| 119 |
Chajka, Vecellio, Hayhoe, & Gillam |
The role of binocular vision in navigating obstacles |
| 120 |
Stankiewicz & Pitts |
Using a Bayesian Model to measure the benefit of visual landmarks and layout topology on human navigation efficiencies |
| Face Perception |
121 |
Peterson, Abbey, & Eckstein |
Information distribution for face identificaiton and its relation to human strategies |
| 122 |
Ramon & Rossion |
What’s lost in prosopagnosia? An investigation of familiar face processing in a single-case of pure prosopagnosia working in a kindergarten |
| 123 |
Schiltz, Jacques, & Rossion |
The spatio-temporal correlates of holistic face perception |
| 124 |
Afraz & Cavanagh |
Spatial limits of face processing: Evidence from face aftereffects |
| 125 |
Dakin & Omigie |
Face space: Distinctiveness, discrimination and dippers |
| 126 |
Meng, Cherian, Gabrieli, Gabrieli, & Sinha |
Using computer vision to probe the neural correlates of categorical face perception |
| 127 |
Oh & Shiffrar |
Apparent motion of the face |
| Attention: Objects, Scenes, and Search |
128 |
Xu & Chun |
Grouping determines object-based selection in human inferior intra-parietal sulcus |
| 129 |
Alvarez & Oliva |
The representation of ensemble visual features outside the focus of attention |
| 130 |
Reddy & Kanwisher |
Category selectivity in the ventral visual pathway confers robustness to clutter and diverted attention |
| 131 |
Turk-Browne, Xu, & Chun |
Dissociating task performance from neural repetition effects in ventral visual cortex |
| Attentional Capture |
132 |
Chen & Modrkoff |
Attentional capture by incongruent cues: An analysis of individual difference |
| Attention: Objects, Scenes, and Search |
133 |
Palmer, Van Wert, Horowitz, & Wolfe |
Getting guidance going |
| 134 |
Itti, Yoshida, Berg, Ikeda, Kato, Takaura, & Isa |
Investigation of spontaneous saccades based on the saliency model in monkeys with unilateral lesion of primary visual cortex |
| Eye Movements: Saccades and Smooth Pursuit |
135 |
Gegenfurtner & Rasche |
Sensory and motor contributions to smooth pursuit variability |
| 136 |
Monteon, Martinez-Trujillo, Wang, & Crawford |
Frames of reference for eye-head gaze shifts evoked during stimulation of the primate frontal eye fields |
| 137 |
Stevenson, Kumar, & Roorda |
Psychophysical and oculomotor reference points for visual direction measured with the adaptive optics scanning laser ophthalmoscope |
| 138 |
Van der Stigchel, van Zoest, & Barton |
The effect of distractors in prosaccade, antisaccade, and memory-guided saccade tasks |
| 139 |
Roy, Oruc, & Barton |
Within-hemifield mutual inteference and repulsion in the programming of antisaccades |
| 140 |
Ludwig & Gilchrist |
A sequential sampling model of saccadic double-steps in direction |
| 141 |
Gowani, Barton, Levin, & Fox |
Prior probability effects and their inter-hemispheric interactions in human prosaccades and antisaccades |
| 142 |
Park & Shimojo |
Corrective saccades drive saccadic adaptation independently of explicit interpretation of retinal error |
| 143 |
Kerzel & Ulmann |
Suppression of steady state smooth pursuit by irrelevant flashes |
| Locomotion I: General |
144 |
Diaz, Phillips, & Fajen |
Locomotor interception of unpredictable moving targets |
| 145 |
Interrante, Ries, O'Rourke, Gray, Lindquist, & Anderson |
Evaluating alternative metaphors for augmented locomotion through large scale immersive virtual environments |
| 146 |
Khomut & Warren |
Catching fly balls in VR: A test of the OAC, LOT and trajectory prediction strategies |
| 147 |
Lappe, Jenkin, & Harris |
Visual odometry by leaky integration |
| 148 |
Severson, Uc, MD, Sparks, BA, & Rizzo, MD |
Effect of UFOV impairment on kinematics of curve driving |
| 149 |
Wann, Field, & Wilkie |
Visual control of locomotor steering: An fMRI study |
| 150 |
Wood, Chaparro, Carberry, & Chu |
Simulated visual impairment affects night-time driving and pedestrian recognition |
| 151 |
Sims & Fajen |
A reinforcement learning model of visually guided braking |
| 152 |
Warren, Bruggeman, & Zosh |
Optic flow serves as a teaching signal for visual-locomotor adaptation |
| 153 |
Dolgov, Todd, Birchfield, McBeath, & Thornburg |
The influence of locomotion on the axis-aligned motion bias in large situated display environments |
| 154 |
Ellard, Wagar, & Eller |
Recalibration of the relationship between visual and action space: Evidence for generalization across actions |
| Visuomotor Control: Hand Movements |
155 |
Bruno & Bernardis |
Visually guided pointing and the Müller-Lyer illusion: why are the data so contradictory? |
| 156 |
Binsted, Ehresman, Heath, & Saucier |
Execution generated illusory motor bias: two systems, one representation |
| 157 |
Franz, Hesse, & Kollath |
Grasping after a delay: More ventral than dorsal? |
| 158 |
Anderson & Bingham |
Evidence for the use of a binocular Tau-dot strategy in visually guided reaching |
| 159 |
Bingham & Anderson |
A binocular Tau-dot model for guiding reaches |
| 160 |
Hesse, de Grave, Franz, Brenner, & Smeets |
Planning movements well in advance |
| 161 |
Heath, Tremblay, & Binsted |
Vision predominates sensorimotor transformations for online grasping control |
| 162 |
Ishak & Adolph |
Gauging affordances for reaching through apertures |
| 163 |
Watt, Keefe, & Hibbard |
Do binocular depth cues have a special role in grasping? |
| 164 |
Khan, Blohm, Ren, & Crawford |
Independent gaze-centered representations of reach targets viewed with left vs. right eye |
| 165 |
Fajen & Cramer |
Visual control of hand position and orientation during one-handed catching |
| 166 |
Thaler & Todd |
Reaching to a point or reaching over a distance - What is the difference? |
| 167 |
Wu, DalMartello, & Maloney |
Performance in rapid, sequential visually-guided pointing movements |
| 168 |
Wu, Klatzky, Shelton, & Stetten |
Learning in image-guided reaching changes the representation-to-action mapping |
| 169 |
Wolfe, Gray, & Maloney |
Constraint induced learning in a visually guided motor task |
| 170 |
Seydell, McCann, Trommershäuser, & Knill |
Human pointing movements in a probabilistic environment |
| 171 |
Hudson, Wolfe, & Maloney |
The covariance structure of speeded reaching movements |
| Attention: Neural Mechanisms |
172 |
Li, Lu, Tjan, Dosher, & Chu |
Attentional modulation of the BOLD-fMRI contrast response functions in early visual areas |
| 173 |
Torralbo, Beck, & Kramer |
Perceptual load-induced selection as a result of neural competition in early visual cortex |
| 174 |
Yang & Ts'o |
The influence of a visual task on fMRI activation patterns in the visual cortex |
| 175 |
Park, Zhang, Ferrera, Hood, & Hirsch |
Spatial distribution of attention effects in human visual cortex |
| 176 |
Ling, Liu, & Carrasco |
Feature-based attention increases gain and sharpens tuning of motion selective channels |
| 177 |
Serences & Boynton |
Perceptual decisionmaking in human visual cortex |
| 178 |
Ciaramitaro & Boynton |
Behavioral measures of cross-modal attention are consistent with fMRI responses in V1 and not MT+ |
| 179 |
Gee, Ipata, & Goldberg |
Activity in monkey V4 reflects target identification and saccade direction in free viewing visual search |
| 180 |
Landau, Esterman, Robertson, & Prinzmetal |
Gamma band levels index voluntary shifts of attention to faces |
| 181 |
Esterman, Verstynen, & Robertson |
Attenuating illusory binding with TMS of the right parietal cortex |
| 182 |
Shalev, Mevorach, Allen, & Humphreys |
Dissociating the cognitive mechanisms of sustained attention and response inhibition: An fMRI study using a conjunctive go/no-go task |
| 183 |
Mevorach, Shalev, Allen, & Humphreys |
The Left inferior parietal lobe modulates the selection of low salient stimuli |
| 184 |
Shomstein, Kravitz, & Behrmann |
Temporal dynamics of an attentional switch |
| Attentional Capture |
185 |
Chua & Ismail |
A new object captures attention |
| Attention: Neural Mechanisms |
186 |
Pitts, Nerger, & Stalmaster |
The role of spatial and selective attention in the perception of bistable images |
| 187 |
Bolduc-Teasdale, Beaupré, Robitaille, & McKerral |
ERP 'blink' instructions revisited: Effects on attention-related processes |
| 188 |
Boehnke, Berg, Baldi, Itti, & Munoz |
Adaptation and habituation of visual responses in the superficial and intermediate layers of the superior colliculus (SC) |
| 189 |
Dranias, Bullock, & Grossberg |
A neural network model of simultaneous visual discrimination: Incentive modulation of visual stimulus salience |
| Scene Perception I |
190 |
Dickinson & Intraub |
Boundary extension in the transsaccadic representation of layout |
| 191 |
Michod & Intraub |
Conceptual Masking: Is it really all about the concept or does layout matter? |
| 192 |
Castelhano, Pollatsek, & Rayner |
Memory for viewpoint changes in naturalistic scenes |
| 193 |
Torralba, Fergus, & Freeman |
Object and scene recognition in tiny images |
| 194 |
MacKenzie, Fortis-Santiago, & Fiser |
Integrating central and peripheral information during object categorization |
| 195 |
Sanocki & Sulman |
Functional representations of layout are disrupted by irrelevant objects |
| 196 |
van der Smagt & Nijboer |
Color information impairs change detection |
| 197 |
Ogmen, Aydin, & Herzog |
Differential perceived speeds explain the apparent compression in slit viewing |
| 198 |
Markovic & Radonjic |
Aspects of painting perception |
| 199 |
Yue, Lescroart, Vessel, & Biederman |
A test of the consistency of scene preferences across cultures |
| 200 |
Li & Matin |
The elevation of Visually Perceived Eye Level (VPEL) is an oscillatory function of visual pitch |
| 201 |
Dixon, Canga, Nikolov, Troscianko, Noyes, Bull, & Canagarajah |
Solider direction and soldier location: Image fusion and compression in two scene perception tasks |
| 2D Shape and Form |
202 |
Loffler, Bennett, & Gordon |
Seeing shape in noise: tuning characteristics of global shape mechanisms |
| 203 |
Pinna |
New local and global shape illusions due to grouping |
| 204 |
Roach, Webb, & McGraw |
Prolonged exposure to global structure induces 'remote' tilt-aftereffects |
| 205 |
Tyler, Kao, & Chen |
The role of 2D and 3D symmetry information in face processing in the human brain |
| 206 |
Sawada & Pizlo |
Perceiving planar symmetric objects in 3D scenes |
| 207 |
Guidi & Palmer |
Symmetry and relational structure in the perception of rectangular frames |
| 208 |
Webb, Roach, & Peirce |
Masking exposes multiple global form mechanisms at intermediate levels of visual processing |
| 209 |
Wilkinson, Shahjahan, & Wilson |
Hysteresis between shape-defined categories |
| 210 |
Haushofer, Baker, & Kanwisher |
Frequency-based categorization of complex visual objects |
| 211 |
Kempgens, Loffler, & Orbach |
When change blindness fails: Factors determining change detection for circular patterns |
| 212 |
Bittner, Wenger, Sullivan, & Von Der Heide |
Dimensional consistency effects with illusory dimensions |
| 213 |
Aydin, Herzog, & Ogmen |
Compression in slit viewing occurs not in space but at object level |
| Special Populations: Development |
214 |
Von Der Heide, Wenger, Gilmore, Walsh, Sullivan, & Bittner |
Developmental changes in the capacity to process faces |
| 215 |
Cantlon, Libertus, Brannon, & Pelphrey |
The development of abstract numerical processing in parietal cortex |
| 216 |
Gori, Del Viva, Sandini, & Burr |
Six-year-old children do not integrate visual-haptic information optimally |
| 217 |
Gilmore, Murray-Kolb, & Lee |
Infants' visual habituation patterns show large within-session variability |
| 218 |
Kruk |
Good-poor reader accuracy differences in four-dot masking |
| 219 |
Taylor & Jakobson |
Representational momentum in preterm and full-term children |
| 220 |
Zosh, Feigenson, & Halberda |
Infants' ability to enumerate multiple spatially-overlapping sets in parallel |
| 221 |
Boutin & Ellemberg |
Spatial lateral interactions during childhood |
| 222 |
Carmi, Tseng, Cameron, Itti, & Munoz |
The impact of maturation and aging on mechanisms of attentional selection |
| V1 and Thalamus: Anatomy and Organization |
223 |
Fischer & Whitney |
Precise topographic encoding of visual stimuli in the human pulvinar |
| 224 |
Leh, Chakravarty, & Ptito |
The connectivity of the human pulvinar: a diffusion tensor imaging tractography study |
| 225 |
Radoeva & Aguirre |
Representation of the ipsilateral visual field in early retinotopic cortex |
| 226 |
Iaria, Robbins, & Petrides |
The human occipital lobe: variability and probability maps of the sulci |
| 227 |
Hansen |
What makes topographic map boundaries parsimonious? |
| Attentional Capture |
228 |
Hodsoll, Mevorach, & Humphreys |
Driven to less distraction: rTMS of the right parietal cortex reduces attentional capture in visual search by eliminating inter-trial priming |
| V1 and Thalamus: Anatomy and Organization |
229 |
Ben Amor & Vaucher |
The effects of a cholinergic deficit on visual learning in rats |
| 230 |
Masuda, Nakadomari, Dumoulin, Cheung, Furuta, Kitahara, & Wandell |
The mechanism underlying large-scale reorganization in human macular degeneration patients |
| 231 |
Pinto, Hornby, Jones, & Murphy |
Changes in inhibitory mechanisms in human visual cortex throughout the lifespan |
| 232 |
James, Goh, & Vanni |
Pattern-pulse multifocal MEG mapping of human visual cortex using the general linear model |
| 233 |
Erlenmeyer, Ales, Carney, & Klein |
Designer stimuli enables VEP based separation of early visual areas |
| Brightness, Lightness and Luminance |
234 |
Allred & Brainard |
Parametric measurements of lightness in the context of real illuminated objects |
| 235 |
Boyaci, Fang, Murray, & Kersten |
Amodal completion affects lightness perception |
| 236 |
Hamburger & Shapiro |
The Hermann grid is an equiluminant weave |
| 237 |
Robinson, Hammon, & de Sa |
A filtering model of brightness perception using Frequency-specific Locally-normalized Oriented Difference-of-Gaussians (FLODOG) |
| 238 |
Zhang, Park, Salant, Thomas, Hirsch, & Hood |
Multiplicative model for spatial interaction in the human visual cortex |
| 239 |
Fukuya & Uchikawa |
The transition luminance between the surface-color and the illuminant-color modes may reveal the illuminant represented in the visual system |
| 240 |
Anderson, Dakin, & Rees |
A sub-cortical locus for brightness filling in |
| 241 |
Horiguchi, Nakadomari, Furuta, Asakawa, Masuda, Kitahara, Abe, Kan, Misaki, & Miyauchi |
Correlation of fMRI responses to absolute luminance changes in visual cortex |
| 242 |
Murray & Boynton |
FMRI responses in V1 represent the perceived rather than physical stimulus contrast |
| 243 |
Pereverzeva & Murray |
Brightness Induction in human V3 |
| 244 |
Marino, Levy, & Munoz |
Target luminance modulates saccadic behavior and visual sensory responses in the superior colliculus |
| 245 |
Lovell, Tolhurst, To, & Troscianko |
Rapid search for gross illumination discrepancies in upright but not inverted images |
| 246 |
Brooks, Tyrrell, & Stephens |
The accuracy of observers' estimates of their ability to see and steer in low luminances |
| 247 |
Martin, Manger, Klein, Tyler, & Brooks |
Preferred driving speeds of older and younger drivers under varying luminance conditions |
| 248 |
Miller, Hilpert, Klein, Tyler, & Brooks |
The effects of fog on driving speed |
| Spatial Vision: Contrast and Masking |
249 |
Haun & Essock |
Anisotropic contrast gain inferred from broadband masking |
| 250 |
Huang & Hess |
Collinear facilitation: effects of additive and multiplicative visual noise |
| 251 |
Govenlock, Bennett, & Sekuler |
An absence of orientation selectivity for visual masking |
| 252 |
Kramer & Olzak |
The effects of collinearity on contrast discrimination tasks |
| 253 |
Olzak & Kramer |
Cross-orientation interactions in second-order mechanisms |
| 254 |
Kurki, Hyvärinen, & Saarinen |
Analysing spatiotemporal dynamics in contrast detection by Classification Images |
| 255 |
Gold, Conrey, & Eidels |
A technique for measuring single-item identification efficiencies |
| 256 |
Manahilov, Gordon, Calvert, & Simpson |
A new subtractive normalization model for contrast processing of visual stimuli |
| 257 |
Medina, Meese, & Mullen |
Cross-orientation masking in the red-green isoluminant and luminance systems |
| 258 |
Saarela & Herzog |
Temporal characteristics and surround modulation of contrast masking |
| 259 |
Aguirre, Barraza, & Colombo |
The effect of glare on visibility depends on spatial frequency |
| 260 |
Chen |
Lateral masking with contrast- and luminance-modulated patterns |
| 261 |
Katkov, Tsodyks, & Sagi |
The human contrast response function: overcoming experimental pitfalls |
| 262 |
Joo & Chong |
Effect of signal strength on attentional blink |
| Adaptation and Aftereffects |
263 |
Czuba, Beer, & MacLeod |
Adaptation and afterimages: A model of inverse multiplicative sensitivity adjustment |
| 264 |
Wolfson & Graham |
More about "Buffy adaptation" |
| 265 |
McGovern & Peirce |
The effect of contrast on adaptation to compound patterns |
| 266 |
Simmons & Durgin |
Frame-contingent density aftereffects: A closer look |
| 267 |
McDermott, Sharma, & Webster |
Adaptation and contrast constancy in natural images |
| 268 |
Ziemer, Plumert, Cremer, & Kearney |
Perceptual adaptation to environmental scale |
| 269 |
Haber, Ballardini, & Webster |
Blur adaptation and induction in the fovea and periphery |
| 270 |
Smith, McLin, Barnes, & Rogers |
Exploring the dynamics of light adaptation by measuring sensitivity against a flickering background |
| 271 |
Krizay, Vul, Shubel, & MacLeod |
Two timescales of orientation-contingent color adaptation |
| 272 |
Gheorghiu & Kingdom |
Spatial properties of curvature encoding revealed by the shape-frequency and shape-amplitude after-effects |
| 273 |
Legault, Allard, & Faubert |
Adaptation to circular patterns influences the perception of distorted squares |
| 274 |
Zotov, Grossmann, & Dobbins |
A rotational aftereffect induced by context |
| 275 |
Wu, Halelamien, Hoeft, & Shimojo |
TMS "instant replay" validated using novel double-blind stimulation technique |
| 276 |
Halelamien, Wu, & Shimojo |
TMS induces detail-rich "instant replays" of natural images |
| 277 |
Wede & Francis |
Cortical dynamics of negative afterimages: Spatial properties of the inducer |
| 278 |
VanHorn & Francis |
Switch color afterimages suggest cortical mechanisms |
| 279 |
Weil, Kilner, Haynes, & Rees |
Neural correlates of perceptual filling-in of an artificial scotoma in humans |
| 280 |
Wykes, Weil, & Rees |
Attentional load modulates time-to filling-in of an artificial scotoma |
| 281 |
Richters & Eskew |
The effect of sensorimotor adaptation on chromatic judgments |
| 3D Perception: Space |
282 |
He, Hong, & Ooi |
On judging surface slant using haptic (palm-board) and verbal-report task |
| 283 |
Akagi & Durgin |
Accurate perception of visual space from live-video in a head-mounted display |
| 284 |
Imura & Tomonaga |
Visual search on the ground-like surface defined by texture gradients in chimpanzees (Pan troglodytes) and humans (Homo sapiens) |
| 285 |
Nadeem & Stankiewicz |
How much can vision tell us about where we are? Measuring the channel capacity between visual perception and spatial layout |
| 286 |
Ozkan & Braunstein |
The position of objects relative to the horizon affects size-distance invariance |
| 287 |
Stefanucci & Storbeck |
Arousal influences the perception of height |
| 288 |
van Doorn, Koenderink, Kappers, Doumen, & Todd |
Exocentric pointing in depth |
| 289 |
Riley, Kelly, Martin, Hayhoe, & Huxlin |
Homonymous hemianopia alters distribution of visual fixations in 3-dimensional virtual environments |
| 290 |
Suzuki & Uehira |
Depth perception of real objects and virtual objects when they are presented at the same depth defined by binocular retinal disparity |
| 291 |
Witt, Linkenauger, Bakdash, & Proffitt |
Golf performance makes the hole look as big as a bucket or as small as a dime |
| Visual Control of Movement: Neural Mechanisms |
292 |
Zettel, Vilis, Culham, & Crawford |
A comparison of saccade and pointing topography between medial and lateral areas in the human posterior parietal cortex |
| 293 |
Vesia, Henriques, Yan, Sergio, & Crawford |
TMS over posterior parietal cortex disrupts the integration of initial hand position information into the reach plan |
| 294 |
Karnik, Heider, & Siegel |
Inferior parietal recordings and behavioral effects of shifting prisms on visually guided reaching |
| 295 |
Fattori, Breveglieri, Marzocchi, Filippini, & Galletti |
Foveal and peripheral reaching activity in the macaque cortical area V6A |
| 296 |
Song, McPeek, & Takahashi |
Target selection for visually-guided reaching in macaque |
| 297 |
Chong, Cunnington, Williams, & Mattingley |
Selectivity of human mirror system responses during observation and execution of congruent versus incongruent hand actions |
| 298 |
Broderick, Striemer, Sparling, Murtha, Corbett, Stewart, & Danckert |
Spatial deficits in visuomotor control along the body midline in a patient with optic ataxia |
| Multisensory Processing |
299 |
Corbett & Carrasco |
Attention enhances visual contributions to multisensory integration for the perception of upright. |
| 300 |
Dyde & Harris |
A (nother) new way to measure up: the oblique derived subjective visual vertical |
| 301 |
Filimon, Nelson, & Sereno |
Human fMRI of tactile spatial representations |
| 302 |
Grove & Sakurai |
Equivalent stream/bounce effects in cyclopean and luminance defined displays |
| 303 |
Harris, Dyde, & Jenkin |
The relative contributions of the visual components of a natural scene in defining the perceptual upright |
| 304 |
Iordanescu, Grabowecky, & Suzuki |
Meaningful association of a sound with a target facilitates visual search |
| 305 |
Kim, Seitz, & Shams |
Visual perceptual learning enhanced with congruent sound |
| 306 |
Schutz & Kubovy |
Musical use of visual gestures: the importance of contextual information in sensory integration |
| 307 |
Serwe, Drewing, & Trommershäuser |
Integration of multi-sensory directional information during goal-directed pointing |
| 308 |
Stephen & Andrej |
Superior visual detection capabilities in congenitally deaf Cats |
| 309 |
Graf, Adams, & Bouzit |
Light priors, learning and feedback |
| Grouping and Segmentation I |
310 |
O'Herron & von der Heydt |
Persistence of the neural border ownership signal indicates short-term memory in perceptual organization |
| 311 |
Brooks & Palmer |
Attention and figure-ground status produce separate steady-state VEP effects in human cortex |
| 312 |
T. Likova & W. Tyler |
Cortical network dynamics of figure/ground categorization |
| 313 |
Rosenholtz, Twarog, & Wattenberg |
Filtering in feature space: a computational model of grouping by proximity and similarity |
| 314 |
Vickery & Jiang |
Second-order perceptual grouping |
| 315 |
Ostrovsky, Wulff, & Sinha |
Learning static Gestalt laws through dynamic experience |
| Eye Movements: Mechanisms |
316 |
DeSouza, Blohm, Yan, Wang, & Crawford |
Superior colliculus (SC) neural activity codes visually guided head-unrestrained gaze movements in retinal coordinates |
| 317 |
Shen & Paré |
Effects of visual salience on superior colliculus neural activity during visual conjunction search. |
| 318 |
Tse, Baumgartner, & Greenlee |
fMRI BOLD signal reveals neural correlates of microsaccades |
| 319 |
Hamker, Zirnsak, & Lappe |
Dynamic receptive field effects predicted by a saccade target theory of visual perception |
| 320 |
Mulligan & Stevenson |
Spontaneous oculomotor oscillations induced by delayed visual feedback |
| 321 |
White, Boehnke, Marino, Talsma, Itti, Theeuwes, & Munoz |
Competition between exogenous and endogenous signals revealed by saccade latency and saccade curvature in the monkey |
| Early Visual Processing: Receptive Fields |
322 |
George & Yao |
Lateral interactions in outer retina disclosed by high resolution dynamic optical imaging of neural activation |
| 323 |
Harrison, Kamitani, Dewey, & Tong |
Neural decoding reveals the orientation-selective properties of early human vis |
