| scholarly article | Q13442814 |
| P356 | DOI | 10.3758/BF03196326 |
| P698 | PubMed publication ID | 12613674 |
| P50 | author | Marisa Carrasco | Q16973893 |
| Cigdem P Talgar | Q125266570 | ||
| P2860 | cites work | Selective attention gates visual processing in the extrastriate cortex | Q28235565 |
| Orienting of attention | Q28282162 | ||
| Organization of texture segregation processing in primate visual cortex | Q72551002 | ||
| Cortical magnification neutralizes the eccentricity effect in visual search | Q73152214 | ||
| Central performance drop in texture segmentation: the role of spatial and temporal factors | Q73294535 | ||
| The importance of sustained attention for patients with maculopathies | Q73731717 | ||
| Sustained focal attention and peripheral letter recognition | Q77296453 | ||
| Spatial attention improves performance in spatial resolution tasks | Q77746402 | ||
| Texture segregation shows only a very small lower-hemifield advantage | Q77797841 | ||
| Covert attention affects the psychometric function of contrast sensitivity | Q77884507 | ||
| Neural mechanisms of selective visual attention | Q28292891 | ||
| The role of neural mechanisms of attention in solving the binding problem | Q33839065 | ||
| Characterizing visual performance fields: effects of transient covert attention, spatial frequency, eccentricity, task and set size | Q35095370 | ||
| Striate cortex extracts higher-order spatial correlations from visual textures | Q35718192 | ||
| Covert attention accelerates the rate of visual information processing | Q35875861 | ||
| Attention improves or impairs visual performance by enhancing spatial resolution | Q37302122 | ||
| Spatial covert attention increases contrast sensitivity across the CSF: support for signal enhancement | Q37302146 | ||
| Attention activates winner-take-all competition among visual filters. | Q41646213 | ||
| Attention mechanisms for multi-location first- and second-order motion perception | Q41733765 | ||
| Effects of spatial cuing on luminance detectability: psychophysical and electrophysiological evidence for early selection | Q44903573 | ||
| Spatial vision thresholds in the near absence of attention | Q46161023 | ||
| Functional anatomy of macaque striate cortex. II. Retinotopic organization. | Q46195848 | ||
| Spatial attention and vernier acuity | Q46446870 | ||
| Effects of lateral masking and spatial precueing on gap-resolution in central and peripheral vision | Q46546458 | ||
| External noise distinguishes attention mechanisms | Q46674369 | ||
| The contribution of covert attention to the set-size and eccentricity effects in visual search | Q47291248 | ||
| Texture segmentation as a function of eccentricity, spatial frequency and target size | Q47361883 | ||
| Set-size effects in visual search: the effect of attention is independent of the stimulus for simple tasks | Q47373157 | ||
| An estimation and application of the human cortical magnification factor | Q48118853 | ||
| Effects of spatial selective attention on the steady-state visual evoked potential in the 20-28 Hz range | Q48447419 | ||
| Feature asymmetries in visual search: effects of display duration, target eccentricity, orientation and spatial frequency | Q48492521 | ||
| The ganglion cell and cone distributions in the monkey's retina: implications for central magnification factors | Q48573610 | ||
| Retinal ganglion cells that project to the superior colliculus and pretectum in the macaque monkey | Q48638119 | ||
| The representation of the visual field in parvicellular and magnocellular layers of the lateral geniculate nucleus in the macaque monkey | Q48645850 | ||
| Attentional resolution and the locus of visual awareness | Q48913701 | ||
| Enhanced perception of illusory contours in the lower versus upper visual hemifields | Q49121766 | ||
| Separation of low-level and high-level factors in complex tasks: visual search | Q49213610 | ||
| Covert attention increases spatial resolution with or without masks: support for signal enhancement. | Q52107085 | ||
| The locus of attentional effects in texture segmentation. | Q52168312 | ||
| Visual search for a tilted target: tests of spatial uncertainty models. | Q52186979 | ||
| Contrast discrimination function: spatial cuing effects. | Q52192827 | ||
| Texture segmentation along the horizontal meridian: nonmonotonic changes in performance with eccentricity. | Q52201417 | ||
| Benefits from attention depend on the target type in location-precued discrimination | Q52229058 | ||
| Sustained and transient components of focal visual attention. | Q52248452 | ||
| Stimulus discriminability in visual search. | Q52371816 | ||
| Texture segregation based on two-dimensional relative phase differences in composite sine-wave grating patterns. | Q52404246 | ||
| A theory of preattentive texture discrimination based on first-order statistics of textons. | Q52745705 | ||
| Visual field asymmetries in pattern discrimination: A sign of asymmetry in cortical visual field representation? | Q67818262 | ||
| Texture segmentation and pop-out from orientation contrast | Q67923587 | ||
| Hemifield differences in perceived spatial frequency | Q68388592 | ||
| Central performance drop on perceptual segregation tasks | Q69148559 | ||
| The eccentricity effect: target eccentricity affects performance on conjunction searches | Q70830509 | ||
| Contrast sensitivity as a function of position on the retina | Q71226909 | ||
| Inattention magnifies perceived length: the attentional receptive field hypothesis | Q71350800 | ||
| The visual field representation in striate cortex of the macaque monkey: asymmetries, anisotropies, and individual variability | Q71410917 | ||
| P433 | issue | 4 | |
| P921 | main subject | attention | Q6501338 |
| P304 | page(s) | 714-722 | |
| P577 | publication date | 2002-12-01 | |
| P1433 | published in | Psychonomic Bulletin and Review | Q15763410 |
| P1476 | title | Vertical meridian asymmetry in spatial resolution: visual and attentional factors. | |
| P478 | volume | 9 |
| Q85689259 | A method for quantifying visual field inhomogeneities |
| Q30976923 | Anatomy of attentional networks |
| Q41883035 | Apparent contrast differs across the vertical meridian: visual and attentional factors |
| Q35069724 | Appraisal of space words and allocation of emotion words in bodily space. |
| Q48189235 | Are vertical meridian effects due to audio-visual interference? A new confirmation with deaf subjects |
| Q48030615 | Asymmetry in Gaze Direction Discrimination Between the Upper and Lower Visual Fields. |
| Q53551365 | Attention Modifies Spatial Resolution According to Task Demands. |
| Q55484596 | Attention alters spatial resolution by modulating second-order processing. |
| Q36371441 | Attention searches nonuniformly in space and in time. |
| Q37688766 | Attentional enhancement of spatial resolution: linking behavioural and neurophysiological evidence |
| Q48961818 | Attentional load modifies early activity in human primary visual cortex |
| Q80546132 | Backward masking and the central performance drop |
| Q37014485 | Behavioral Differences in the Upper and Lower Visual Hemifields in Shape and Motion Perception |
| Q34749253 | Brightness induction and suprathreshold vision: effects of age and visual field |
| Q34064178 | Comparing reading speed for horizontal and vertical English text |
| Q77884507 | Covert attention affects the psychometric function of contrast sensitivity |
| Q37592714 | Covert attention effects on spatial resolution |
| Q31063200 | Covert attention increases contrast sensitivity: Psychophysical, neurophysiological and neuroimaging studies |
| Q30833848 | Covert spatial attention is functionally intact in amblyopic human adults |
| Q36934861 | Cue contrast modulates the effects of exogenous attention on appearance |
| Q47973804 | Delayed saccade to perceptually demanding locations in Parkinson's disease: analysis from the perspective of the speed-accuracy trade-off |
| Q36321553 | Differential effects of exogenous and endogenous attention on second-order texture contrast sensitivity |
| Q84444861 | Differential effects of transient attention on inferred parvocellular and magnocellular processing |
| Q33886659 | Directional processing within the perceptual span during visual target localization |
| Q33960789 | Effect of action video games on the spatial distribution of visuospatial attention |
| Q51969697 | Effects of perceptual learning on primary visual cortex activity in humans. |
| Q84655477 | Effects of visual environment complexity on saccade performance in humans with different functional asymmetry profiles |
| Q42099836 | Exogenous attention enhances 2nd-order contrast sensitivity |
| Q35038096 | Gaining the upper hand: evidence of vertical asymmetry in sex-categorisation of human hands. |
| Q36421688 | How Attention Affects Spatial Resolution |
| Q90024510 | How exogenous spatial attention affects visual representation |
| Q90656385 | How visual spatial attention alters perception |
| Q33561907 | Independent effects of motivation and spatial attention in the human visual cortex |
| Q51502302 | Inhibition of saccade and vergence eye movements in 3D space. |
| Q35937604 | Isoeccentric locations are not equivalent: the extent of the vertical meridian asymmetry |
| Q91710151 | Larger Head Displacement to Optic Flow Presented in the Lower Visual Field |
| Q37310892 | Letter-recognition and reading speed in peripheral vision benefit from perceptual learning |
| Q53025411 | Magnocellular and parvocellular visual pathway contributions to visual field anisotropies. |
| Q84326232 | Misperceiving space following shifts of attention: determining the locus of the attentional repulsion effect |
| Q92269652 | Modeling visual performance differences 'around' the visual field: A computational observer approach |
| Q35781642 | Neural correlates of the visual vertical meridian asymmetry |
| Q80938254 | No evidence of a lower visual field specialization for visuomotor control |
| Q50600085 | Numerosity processing in early visual cortex. |
| Q55332312 | On spatial attention and its field size on the repulsion effect. |
| Q51684137 | On the benefits of transient attention across the visual field. |
| Q43185109 | On the flexibility of sustained attention and its effects on a texture segmentation task |
| Q36971741 | Perceptual asymmetries are preserved in short-term memory tasks |
| Q36990744 | Perceptual consequences of visual performance fields: the case of the line motion illusion |
| Q45107472 | Structural and functional correlates of visual field asymmetry in the human brain by diffusion kurtosis MRI and functional MRI. |
| Q60907713 | Temporal attention improves perception similarly at foveal and parafoveal locations |
| Q79878604 | Temporal performance fields: visual and attentional factors |
| Q48117183 | The effects of inverting prisms on the horizontal-vertical illusion: a systematic effect of downward gaze |
| Q30449827 | The effects of task difficulty on visual search strategy in virtual 3D displays |
| Q28690862 | The optic chiasm: a turning point in the evolution of eye/hand coordination |
| Q50351613 | The upper-hemifield advantage for masked face processing: Not just an attentional bias |
| Q42010924 | The what and why of perceptual asymmetries in the visual domain |
| Q37089153 | Transient attention does increase perceived contrast of suprathreshold stimuli: a reply to Prinzmetal, Long, and Leonhardt (2008) |
| Q50581033 | Upper-lower visual field asymmetries in oculomotor inhibition of emotional distractors. |
| Q36077550 | Visual attention: the past 25 years |
| Q34023556 | Visual performance fields: frames of reference |
| Q42422153 | Voluntary attention increases perceived spatial frequency |
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