| 1 |
Banks, Watt, & Ernst |
Screen cues to flatness affect 3D percepts |
| 2 |
Ward |
A wide field, high dynamic range, stereographic viewer |
| 3 |
Loomis |
Using immersive virtual reality to study visual space perception, visual control of locomotion, and visually-based navigation |
| 4 |
Dagnelie |
Visual performance under simulated conditions of prosthetic vision |
| 5 |
Thomas, Weerda, Vallines, & Greenlee |
Comparison of fMRI responses during discrimination under certainty and uncertainty conditions |
| 6 |
Kontsevich & Tyler |
A single-channel model for spatio-temporal contrast sensitivity at low-to-medium spatial frequencies |
| 7 |
Wichmann |
Modelling contrast transfer in spatial vision |
| 8 |
Cohn |
Of icebergs and spike codes: Titanic theories? |
| 9 |
Sun, Lee, White, & Swanson |
Examination of mechanisms underlying the frequency-doubling illusion |
| 10 |
Baldassi & Verghese |
Effects of spatial and feature cues on the tuning function for orientation and location |
| 11 |
Boynton & Duncan |
Visual acuity correlates with cortical magnification factors in human V1 |
| 12 |
Engel |
FMRI measurements of changes in color and orientation tuning in V1 |
| 13 |
Heeger |
Neuronal correlates of contrast detection and discrimination |
| 14 |
Lee |
How ganglion cells code luminance and chromatic information in natural enviroments |
| 15 |
MacLeod |
Color discrimination, color constancy and natural scene statistics |
| 16 |
Endrikhovski |
A computational model of color categorization based on statistics of natural images |
| 17 |
Lappin & Tadin |
Spatial and temporal limits in discriminating motion energy |
| 18 |
Cantor & Schor |
The flash-lag effect in moving vernier |
| 19 |
Poggel, Kasten, Strasburger, & Sabel |
Residual vision enhanced by visuo-spatial cueing: Attention effects on diagnosis and training of visual field defects in brain-lesioned patients |
| 20 |
Mulligan & Stevenson |
Speed-dependent delays for smooth eye movements |
| 21 |
Murray, Beutter, Eckstein, & Stone |
Saccadic targetting during visual search for letters |
| 22 |
Yang |
Visual countermanding paradigm: How demanding is it to generate a stop signal for eye movements using visual cues? |
| 23 |
Rudd & Zemach |
A quantitative model of achromatic color induction based on separate lightness and darkness filling-in processes |
| 24 |
Chen & Tyler |
Lateral masking with chromoluminance patterns |
| 25 |
Davis & De Valois |
Measuring the role of chromatic saturation and luminance contrast in color spreading using hue cancellation |
| 26 |
Shevell & Cao |
Temporal nulling of chromatic assimilation |
| 27 |
Monnier & Shevell |
s=S/(L+M) color shifts modulated by l=L/(L+M) contrast within patterned backgrounds |
| 28 |
Bimler & Kirkland |
Sex differences in color vision and the salience of color-space axes |
| 29 |
Calver, Radhakrishnan, Pardhan, & OLeary |
The effect of spherical aberration in myopic and non-myopic eyes: developing an optical model |
| 30 |
Davies & Morland |
Chromatic and achromatic spectral sensitivity in diabetes mellitus |
| 31 |
Delahunt, Webster, Ma, & Werner |
A long-term chromatic adaptation mechanism |
| 32 |
Malkoc, Kay, & Webster |
Individual differences in unique and binary hues |
| 33 |
Mizokami, Werner, Crognale, & Webster |
Color appearance and spectral bandwidth |
| 34 |
Hirayama & Shinomori |
Spatial frequency dependence of the luminous impulse response |
| 35 |
Hong & Shevell |
Brightness induction with patterned backgrounds |
| 36 |
Lott, Haegerstrom-Portnoy, Schneck, & Brabyn |
Reading performance in older adults: The SKI study |
| 37 |
Schneck, Haegerstrom-Portnoy, Lott, & Brabyn |
Predicting declines in vision and vision performance in older individuals |
| 38 |
Fine |
Reading eye movements in older adults |
| 39 |
Sakai, Kannon, Hirata, & Usui |
Influence of the eye refraction on the luminance-pupil diameter relationship |
| 40 |
Shinomori & Werner |
The impulse response of an S-cone pathway |
| 41 |
Thibos, Bradley, & Applegate |
Where is the far-point in aberrated eyes? |
| 42 |
Tran, Kuo, & Wildsoet |
The interacting effects of form-deprivation and myopic defocus imposed locally on the central and peripheral retina in chick eyes |
| 43 |
Yew, Chan, & Wildsoet |
Negative 30 D lenses behave like occluders in inducing myopia in young chicks |
| 44 |
Kay |
Color categories are not arbitrary |
| 45 |
D'Zmura |
Color scission and transparency |
| 46 |
Morland & Hoffmann |
Retinotopic organisation of the visual cortex in human albinism |
| 47 |
Kiorpes & Movshon |
Extended developmental time course for global visual functions in primates |
| 48 |
Dobson, Miller, Harvey, & Mohan |
Amblyopia in astigmatic preschool children |
| 49 |
Lawton |
Reading performance by dyslexics was improved by brief practice on a movement discrimination task, but not improved with a word discrimination task |
| 50 |
Chien & Bronson-Castain |
Lightness constancy in 4-month-old infants: With and without a white anchoring point cue |
| 51 |
Good, Hou, & Norcia |
Sweep VEP vernier acuity for the detection of amblyopia |
| 52 |
Eskew, Wang, & Giulianini |
Spectral asymmetries in detection mechanisms fed by S cone increments and decrements. |
| 53 |
Dobkins & Gunther |
Chromatic Contrast Sensitivity is Constrained by the Relative Number of L- vs. M- cones in the Eye |
| 54 |
Smithson & Pokorny |
Psychophysical assessment of the L:M weighting of inputs to the ON and OFF S-cone pathways |
| 55 |
Miyahara, Szewczyk, & Holloway |
Unique hues, Rayleigh match, and favorite colors: Why do we see different colors than others? |
| 56 |
Angel, Randell, Volbrecht, & Nerger |
The effect of rods on perceptive field sizes at 10 degrees eccentricity in the four retinal quadrants |
| 57 |
Thomas & Buck |
Generality of rod hue biases |
| 58 |
Gallant |
Contextual effects in V1 and V4 during natural vision |
| 59 |
Stoner |
Contextual influences of shadows on motion interpretation |
| 60 |
Albright |
Why do things look as they do?: Contextual influences on visual processing |
| 61 |
Nagy |
Color mechanisms and attention in search tasks |
| 62 |
Gegenfurtner |
Color vision and motor control |
| 63 |
Switkes |
Integration of differing chromaticities in early and midlevel spatial vision |
| 64 |
De Valois, Takeuchi, & Hardy |
The role of color in luminance motion analysis |
| 65 |
Henry |
Field studies of color perception in the natural environment |
| 66 |
Fine, MacLeod, & Boynton |
Surface segmentation based on the luminance and color statistics of natural scenes |
| 67 |
Chen & Cicerone |
A new color vision test based on color from motion |
| 68 |
Shady, MacLeod, Fisher, & Liang |
Adaptation from invisible luminance and chromatic flicker |
| 69 |
Simmons |
Stereopsis at red-green isoluminance: Chasing the luminance artifacts |
| 70 |
Krauskopf & Forte |
Independent chromatic and luminance mechanisms for stereo depth? |
| 71 |
Glaser, Kumar, & Zelano |
Stereo depth using excitable neuronal arrays |
| 72 |
Tyler, Likova, & Baseler |
Principles of surface reconstruction |
| 73 |
van Ee |
Voluntarily controlled percepts, will-power, and conscious vision |
| 74 |
McKee, Verghese, & Farell |
Edges and gratings: Interactions between 1st and 2nd order stereo systems |
| 75 |
Stevenson |
Disparity vergence responses to luminance and contrast-defined patterns |
| 76 |
Sperling |
Intertwined mechanisms of motion perception and attention |
| 77 |
Usui |
VISIOME Environment: Web based platform on vision science |
| 78 |
Shokhirev |
Simulation of population activity induced by moving stimuli in the mammalian primary visual cortex |
| 79 |
Disch, Takeuchi, & De Valois |
Apparent speed of cycloidal motions |
| 80 |
Ellis & Adelstein |
Use of kinesthetic cues for cross modal transfer of movement coordinate information or "Why the left hand tells the right hand what it is doing" |
| 81 |
Turano, Eisinger, Chaudhury, Hicks, & Chivukula |
Sex differences in the influence of context on spatial localization revealed in open-loop walking |
| 82 |
Howard & Duke |
Depth from monocular transparency |
| 83 |
Likova & Tyler |
Spatiotemporal relationships in a dynamic scene: Position interruption and transient synchronization in stereomotion induction |
| 84 |
Mirabella & Norcia |
Neural correlates of Kaniza's polarized gamma motion |
| 85 |
Chakor, Bertone, Faubert, McKerral, & Lachapelle |
Do more complex stimuli require more processing time? |
| 86 |
Lachapelle, Rufiange, Brûlé, Racine, Dumont, & Casanova |
The human photopic ERG luminance-response function: Analysis, interpretation and application |
| 87 |
Fulton |
Rod photoreceptor processes in pediatric disorders |
| 88 |
Pei, Bonneh, Sampath, Hou, & Norcia |
Texture detection in infants |
| 89 |
Norcia & Hou |
Non-linear analysis of the contrast paradox for vernier acuity |
| 90 |
Peterzell & Werner |
Rod spatial channels and adult aging: Implications for analysis of development of infant spatial vision |
| 91 |
Wang |
The effect of undersampling, irregular sampling and parafoveal scotomas on shape discrimination |
| 92 |
Westall, Morong, Buncic, & Logan |
Importance of baseline for electrophysiology assessment of drug induced changes in children with seizures. |
| 93 |
Morong, Westall, Buncic, Snead, Logan, & Weiss |
Sweep visual evoked potentials in infants with infantile spasms before and during vigabatrin treatment |
| 94 |
Hood |
Multifocal ERGs and VEPs: Noninvasive studies of the electrical activity of the human visual pathway |
| 95 |
MacKeben |
Kinesthetic feedback augments self-exploration of the visual field after central vision loss |
| 96 |
Demirel, Takahashi, & Johnson |
A comparison of visual field indices for standard FDT and a spatially finer testing pattern |
| 97 |
Tzekov, Gerth, & Werner |
Localized functional age-related changes in the central retina assessed by multifocal ERG |
| 98 |
Swanson & Pan |
A neural model of perimetry in glaucoma |
| 99 |
Porciatti & Ventura |
Screening for glaucoma with a user-friendly paradigm for the PERG called PERGLA. |
| 100 |
Johnson, Takahashi, & Demirel |
The ability of frequency doubling technology (FDT) perimetry to predict the onset of glaucomatous visual field loss for standard automated perimetry (SAP) |
| 101 |
Movshon, Cavanaugh, & Bair |
The role of horizontal intracortical connections in "long-range" spatial interactions |
| 102 |
Varadharajan & Foley |
Effect of flanking patterns on contrast discrimination at different eccentricities |
| 103 |
Xing & Heeger |
Spatial interactions are different at threshold and suprathreshold contrasts |
| 104 |
Olzak, Clark, & Laurinen |
The role of a gap in contextual effects on discrimination performance |
| 105 |
McCourt & Blakeslee |
Spatial frequency influences on brightness in White's effect and the checkerboard illusion. |
| 106 |
Zemach & Rudd |
Blocking of achromatic color induction signals by borders of different contrast polarities |
| 107 |
Birch & Hood |
The full-field ERG as an outcome measure for treatment trials in hereditary retinal diseases |
| 108 |
Alexander & Levine |
Temporal frequency characteristics of period doubling in the cone flicker ERG |
| 109 |
McLellan |
Wave aberrations protect the eye against chromatic blur |
| 110 |
Klein |
Specifying wavefront aberrations for clinical applications: Beyond Zernikes. |
| 111 |
Campbell, Kisilak, Hunter, Bueno, King, & Irving |
Optical aberrations of the eye and eye growth: Why aberrations may be important to understanding refractive error development |
| 112 |
Fortune |
Local functional losses upstream from focal intraretinal laser axotomy in macaque retina |
| 113 |
Hamer, Nicholas, Tranchina, & Liebman |
On the reproducibility of single photon responses (SPRs): the gordian knot of rod phototransduction perseveres |
| 114 |
Gerth, Shinomori, Sutter, & Werner |
The impulse response of the aging visual system: Comparison of psychophysical and electrophysiological data |
| 115 |
Han, Bearse, Schneck, Adams, Barez, & Jacobsen |
Comparison of multifocal electroretinogram (mfERG) measurement techniques to detect diabetic retinopathy |
| 116 |
Marmor |
Clinical electrophysiology and the changing definition of central serous chorioretinopathy |
| 117 |
Bearse, Han, Schneck, & Adams |
Mapping retinal dysfunction in diabetics using the slow flash multifocal electroretinogram |
| 118 |
Marmor |
Failing visual acuity and the late style of Edgar Degas: An optical blur analysis |
| 119 |
Atchison, Marcos, & Scott |
Visual acuity, contrast sensitivity, and phase transfer function depend on the Stiles Crawford peak location |
| 120 |
Miller, Sherrill, Harvey, & Dobson |
The stability of astigmatism in native american preschool children |
| 121 |
Cheng, Himebaugh, Kollbaum, Thibos, & Bradley |
Validation of a clinical aberrometer |
| 122 |
Kollbaum, Cheng, Himebaugh, Thibos, & Bradley |
Stability of clinical aberrometry measurements |
| 123 |
Vilupuru, Roorda, & Glasser |
Changes in ocular aberrations during accommodation in rhesus monkeys |
| 124 |
Abbey, Shimozaki, Baydush, Catarious, Floyd, & Eckstein |
Classification images for the detection of a simulated mass in mammographic images |
| 125 |
Carney, Hill, & Chen |
W4M – A tool to simplify psychophysical research |
| 126 |
Ernst & Banks |
Using visual and haptic information for discriminating objects |
| 127 |
Pelz, Canosa, & Babcock |
Perceptual strategies in complex, extended tasks |
| 128 |
Kaping, Duhamel, & Webster |
Adaptation to natural facial categories |
| 129 |
Neumann & Gegenfurtner |
Perception based image retrieval |
| 130 |
Hou & Norcia |
Neural correlates of shape-from-shading |
| 131 |
Kumar, Jonkers, & Glaser |
Visual texture perception: Differences and similarities among human observers |
| 132 |
Li & Levi |
Mechanisms of perceptual learning for vernier acuity |
| 133 |
Liu & White |
A computational model for discrimination of even and random textures |
| 134 |
Massof, Brown, Shapiro, Barnett, & Baker |
Having your cake and eating it too: Wide field of view and high resolution VR |
| 135 |
Petrov & Popple |
Effects of negative afterimages in visual illusions |
| 136 |
Popple, Levi, & Klein |
Popout templates in amblyopic observers vary with eye-of-origin |
| 137 |
Scharff & Ahumada |
Using letter identifiability to predict readability of transparent text on textured background |
| 138 |
Shimozaki, Eckstein, & Abbey |
Uncertain humans in a structurally certain world: attentional leaking with 100% valid postcues as seen by classification images |
| 139 |
Toyofuku & Klein |
Internal and external noise contributions to classification templates: A double pass analysis |
