| scholarly article | Q13442814 |
| P2093 | author name string | R. Sekuler | |
| E. Levinson | |||
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| P433 | issue | 2 | |
| P407 | language of work or name | English | Q1860 |
| P921 | main subject | physiology | Q521 |
| P1104 | number of pages | 20 | |
| P304 | page(s) | 347-366 | |
| P577 | publication date | 1975-09-01 | |
| P1433 | published in | Journal of Physiology | Q7743612 |
| P1476 | title | The independence of channels in human vision selective for direction of movement | |
| P478 | volume | 250 |
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| Q73948200 | Colour adaptation modifies the temporal properties of the long- and middle-wave cone signals in the human luminance mechanism |
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| Q77797763 | Global-motion detection with transparent-motion signals |
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| Q41711248 | Infant temporal contrast sensitivity functions (tCSFs) mature earlier for luminance than for chromatic stimuli: evidence for precocious magnocellular development? |
| Q92877813 | Interaction between motion scales: When performance in motion discrimination is worse for a compound stimulus than for its integrating components |
| Q73412661 | Interocular interactions reveal the opponent structure of motion mechanisms |
| Q30855751 | Invisible noise obscures visible signal in insect motion detection |
| Q47242627 | Is the size aftereffect direction selective? |
| Q48257558 | Isolating motion responses in visual evoked potentials by preadapting flicker-sensitive mechanisms |
| Q42736503 | Low-level mechanisms do not explain paradoxical motion percepts |
| Q70628818 | Masking by light and the sustained-transient dichotomy |
| Q51645844 | Mechanisms of visual motion detection. |
| Q48254837 | Microstimulation of visual cortex affects the speed of perceptual decisions |
| Q70892002 | Monocular and binocular detection of moving sinusoidal gratings |
| Q71684212 | Monocular mechanisms determine plaid motion coherence |
| Q52771396 | Motion and vision II Stabilized spatio-temporal threshold surface |
| Q52241653 | Motion detection on flashed, stationary pedestal gratings: evidence for an opponent-motion mechanism. |
| Q41683717 | Motion opponency in visual cortex |
| Q55969405 | Motion perception during saccadic eye movements |
| Q36945126 | Motion processing, directional selectivity, and conscious visual perception in the human brain |
| Q83312311 | Motion transparency from opposing luminance modulated and contrast modulated gratings |
| Q41747538 | Neural correlates of contrast detection at threshold |
| Q52535160 | Oscillatory motion but not pattern reversal elicits monocular motion VEP biases in infantile esotropia. |
| Q52247374 | Overprediction and blocking in the McCollough aftereffect. |
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| Q71774089 | Rapid motion aftereffect seen within uniform flickering test fields |
| Q42320586 | Reducing luminance intensity can improve motion perception in noise |
| Q71002450 | Residual vision in humans who have been monocularly deprived of pattern stimulation in early life |
| Q69201417 | Saccadic eye movements and the detection of fast-moving gratings |
| Q73651314 | Sampling efficiency and internal noise for motion detection, discrimination, and summation |
| Q28742822 | Stimulus fractionation by interocular suppression |
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| Q44788584 | The detection of the motion of contrast modulation: a parametric study |
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| Q93076026 | Visual Cortical Plasticity in Retinitis Pigmentosa |
| Q48263960 | Visual movement perception in the cat is directionally selective |
| Q33609873 | What causes alternations in dominance during binocular rivalry? |
| Q49027757 | What does the Ternus display tell us about motion processing in human vision? |
| Q50689505 | When S-cones contribute to chromatic global motion processing. |
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