scholarly article | Q13442814 |
P2093 | author name string | Yury Petrov | |
Olga Meleshkevich | |||
P2860 | cites work | Crowding is unlike ordinary masking: distinguishing feature integration from detection | Q81317874 |
Attentional modulation of crowding | Q82737837 | ||
Effect of colour pop-out on the recognition of letters in crowding conditions | Q83827686 | ||
Psychophysics of reading. XX. Linking letter recognition to reading speed in central and peripheral vision | Q33937945 | ||
Seeing beyond the receptive field in primary visual cortex | Q34029080 | ||
Visual spatial attention to multiple locations at once: the jury is still out. | Q34113416 | ||
Visual attention within and around the field of focal attention: a zoom lens model | Q34190612 | ||
Crowding and surround suppression: not to be confused | Q36614669 | ||
Crowding is directed to the fovea and preserves only feature contrast | Q36700835 | ||
Crowding: a cortical constraint on object recognition | Q36761116 | ||
Adult cortical dynamics | Q41751235 | ||
Independent hemispheric attentional systems mediate visual search in split-brain patients. | Q45947916 | ||
Spatial resolution for feature binding is impaired in peripheral and amblyopic vision | Q46274779 | ||
The roles of cortical image separation and size in active visual search performance | Q47251141 | ||
The shape and size of crowding for moving targets | Q47439427 | ||
Factors limiting peripheral pattern discrimination | Q48243631 | ||
Costs and benefits of integrating information between the cerebral hemispheres: a computational perspective | Q48425600 | ||
The dynamics of interhemispheric collaboration and hemispheric control | Q48445503 | ||
Vernier acuity, crowding and cortical magnification | Q48545930 | ||
Can the spotlight of attention be shaped like a doughnut? Evidence from steady-state visual evoked potentials | Q48639107 | ||
Attentional resolution and the locus of visual awareness | Q48913701 | ||
The spatial resolution of visual attention | Q49029201 | ||
Crowding, feature integration, and two kinds of "attention". | Q50480785 | ||
Selective Bayes: attentional load and crowding. | Q51700796 | ||
Precueing attention to the target location diminishes crowding and reduces the critical distance. | Q51898786 | ||
Compulsory averaging of crowded orientation signals in human vision. | Q52059943 | ||
Bayesian adaptive estimation of psychometric slope and threshold. | Q52204416 | ||
Masking and the identification of characters presented simultaneously and sequentially to the parafovea. | Q52290200 | ||
Feature mislocalizations and misjudgments of intercharacter distance. | Q52290369 | ||
Visual interference in the parafoveal recognition of initial and final letters of words | Q52322078 | ||
Locus of spatial attention determines inward-outward anisotropy in crowding. | Q53082812 | ||
The two-dimensional shape of spatial interaction zones in the parafovea | Q58039811 | ||
Erratum: Sustained division of the attentional spotlight | Q59090075 | ||
Interaction Effects in Parafoveal Letter Recognition | Q59090971 | ||
The effect of similarity and duration on spatial interaction in peripheral vision | Q59210773 | ||
Attention and the detection of signals | Q60307342 | ||
A Study of Separation Difficulty* | Q63230017 | ||
Asymmetry of visual interference | Q66947968 | ||
Lateral interactions in peripherally viewed texture arrays | Q73684645 | ||
VISUAL RESOLUTION AND CONTOUR INTERACTION | Q76568916 | ||
Horizontal and vertical asymmetry in visual spatial crowding effects | Q80544869 | ||
P433 | issue | 10 | |
P304 | page(s) | 1117-1123 | |
P577 | publication date | 2011-03-23 | |
P1433 | published in | Vision Research | Q1307852 |
P1476 | title | Asymmetries and idiosyncratic hot spots in crowding | |
P478 | volume | 51 |
Q41419974 | Age-related changes in crowding and reading speed |
Q37309519 | Cortical reorganization after long-term adaptation to retinal lesions in humans |
Q34110373 | Crowding by invisible flankers |
Q33751545 | Diagnosing the Periphery: Using the Rey-Osterrieth Complex Figure Drawing Test to Characterize Peripheral Visual Function |
Q35007213 | Effects of crowding and attention on high-levels of motion processing and motion adaptation |
Q39952470 | Flipping the stimulus: Effects on scanpath coherence? |
Q64078432 | Image content is more important than Bouma's Law for scene metamers |
Q41655372 | Image correlates of crowding in natural scenes. |
Q35081468 | Individual differences in visual field shape modulate the effects of attention on the lower visual field advantage in crowding |
Q33639534 | Integrating retinotopic features in spatiotopic coordinates |
Q37722014 | Interaction between stimulus contrast and pre-saccadic crowding. |
Q64235196 | Linkage between retinal ganglion cell density and the nonuniform spatial integration across the visual field |
Q86546812 | Perception of differences in naturalistic dynamic scenes, and a V1-based model |
Q34519216 | Radial-tangential anisotropy of crowding in the early visual areas |
Q64882649 | Running Large-Scale Simulations on the Neurorobotics Platform to Understand Vision - The Case of Visual Crowding. |
Q96136032 | Seven Myths on Crowding and Peripheral Vision |
Q34936944 | Shorter lines facilitate reading in those who struggle |
Q37320003 | The crowding factor method applied to parafoveal vision |
Q33620079 | Variations in crowding, saccadic precision, and spatial localization reveal the shared topology of spatial vision |
Q49833031 | Visual Working Memory Is Independent of the Cortical Spacing Between Memoranda |
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