| scholarly article | Q13442814 |
| P2093 | author name string | Zhong-Lin Lu | |
| Barbara Anne Dosher | |||
| Wilson Chu | |||
| P2860 | cites work | The Psychophysics Toolbox | Q27861071 |
| The VideoToolbox software for visual psychophysics: transforming numbers into movies | Q29547363 | ||
| Visual perception: Learning to see through noise | Q33879721 | ||
| Perceptual learning in clear displays optimizes perceptual expertise: learning the limiting process | Q33935033 | ||
| Independent perceptual learning in monocular and binocular motion systems | Q33936745 | ||
| Psychophysics: Is subliminal learning really passive? | Q34181946 | ||
| Three-systems theory of human visual motion perception: review and update | Q34364658 | ||
| Perceptual learning reflects external noise filtering and internal noise reduction through channel reweighting | Q36818344 | ||
| Learning letter identification in peripheral vision | Q37340970 | ||
| Where practice makes perfect in texture discrimination: evidence for primary visual cortex plasticity | Q37527112 | ||
| Accurate control of contrast on microcomputer displays | Q39250623 | ||
| Perceptual learning: learning to see. | Q40676219 | ||
| Practice improves adults' sensitivity to diagonals | Q41608556 | ||
| Characterizing human perceptual inefficiencies with equivalent internal noise | Q41611712 | ||
| Mechanisms of perceptual attention in precuing of location | Q41733076 | ||
| Perceptual learning in object recognition: object specificity and size invariance | Q41737074 | ||
| Improvement in line orientation discrimination is retinally local but dependent on cognitive set | Q43491154 | ||
| Spatial frequency adaptation can enhance contrast sensitivity | Q43911349 | ||
| Improvement in vernier acuity with practice | Q44160472 | ||
| Fast perceptual learning in visual hyperacuity | Q44712446 | ||
| Perceptual learning for a pattern discrimination task. | Q46058584 | ||
| Level and mechanisms of perceptual learning: learning first-order luminance and second-order texture objects | Q46098913 | ||
| Noise exclusion in spatial attention | Q46509437 | ||
| External noise distinguishes attention mechanisms | Q46674369 | ||
| The functional architecture of human visual motion perception | Q46966904 | ||
| Effects of foreground scale in texture discrimination tasks: performance is size, shape, and content specific. | Q47402122 | ||
| Learning pop-out detection: building representations for conflicting target-distractor relationships | Q48303503 | ||
| Spatial attention excludes external noise at the target location | Q48343488 | ||
| Simultaneous learning of motion discrimination in two directions | Q48447257 | ||
| Greater plasticity in lower-level than higher-level visual motion processing in a passive perceptual learning task | Q48490419 | ||
| Task difficulty and the specificity of perceptual learning | Q48705538 | ||
| Learning pop-out detection: specificities to stimulus characteristics | Q48870362 | ||
| Generating high gray-level resolution monochrome displays with conventional computer graphics cards and color monitors | Q51806152 | ||
| Compulsory averaging of crowded orientation signals in human vision. | Q52059943 | ||
| Perceptual learning retunes the perceptual template in foveal orientation identification. | Q52092761 | ||
| Perceptual learning improves efficiency by re-tuning the decision 'template' for position discrimination. | Q52094853 | ||
| Signal but not noise changes with perceptual learning. | Q52171462 | ||
| Mechanisms of perceptual learning. | Q52172165 | ||
| Perceptual learning in primary and secondary motion vision. | Q52176863 | ||
| Contrast masking effects change with practice. | Q52193717 | ||
| Three remarks on perceptual learning. | Q52203659 | ||
| Perceptual learning in parafoveal vision | Q52208001 | ||
| Human perceptual learning in identifying the oblique orientation: retinotopy, orientation specificity and monocularity. | Q52209478 | ||
| Perceptual learning in vernier acuity: what is learned? | Q52210150 | ||
| The time course of learning a visual skill. | Q52222874 | ||
| Long-term learning in vernier acuity: effects of stimulus orientation, range and of feedback. | Q52227327 | ||
| Interhemispheric transfer of visual information in humans: spatial characteristics. | Q52257268 | ||
| Direction-specific improvement in motion discrimination. | Q52258245 | ||
| The effect of practice on the oblique effect in line orientation judgments. | Q52270813 | ||
| Learning in grating waveform discrimination: Specificity for orientation and spatial frequency | Q52295155 | ||
| Perceptual learning specific for orientation and spatial frequency. | Q52297209 | ||
| Orientation-specific learning in stereopsis. | Q52322951 | ||
| Acquisition of cognitive skill | Q56566697 | ||
| A specific and enduring improvement in visual motion discrimination | Q70495884 | ||
| Efficiency of human visual signal discrimination | Q70924819 | ||
| Why use noise? | Q74588719 | ||
| P433 | issue | 15 | |
| P921 | main subject | motion detection | Q852453 |
| fovea centralis | Q865103 | ||
| P304 | page(s) | 2315-2327 | |
| P577 | publication date | 2006-03-09 | |
| P1433 | published in | Vision Research | Q1307852 |
| P1476 | title | Perceptual learning of motion direction discrimination in fovea: separable mechanisms | |
| P478 | volume | 46 |
| Q36568943 | A Weber-like law for perceptual learning |
| Q35581106 | Aging, perceptual learning, and changes in efficiency of motion processing |
| Q37104038 | An integrated reweighting theory of perceptual learning |
| Q64058365 | Assessing the detailed time course of perceptual sensitivity change in perceptual learning |
| Q33540193 | Category and perceptual learning in subjects with treated Wilson's disease |
| Q36662995 | Differences in the time course of learning for hard compared to easy training. |
| Q61798289 | Disentangling locus of perceptual learning in the visual hierarchy of motion processing |
| Q42113138 | Electrophysiological correlates of learning-induced modulation of visual motion processing in humans |
| Q92025310 | Evaluating the performance of the staircase and quick Change Detection methods in measuring perceptual learning |
| Q33825546 | MECHANISMS OF PERCEPTUAL LEARNING |
| Q33840868 | Mechanisms underlying perceptual learning of contrast detection in adults with anisometropic amblyopia |
| Q41995173 | Perceptual learning and aging: improved performance for low-contrast motion discrimination |
| Q91233085 | Perceptual learning of Vernier discrimination transfers from high to zero noise after double training |
| Q97686957 | Perceptual learning of motion direction discrimination: Location specificity and the uncertain roles of dorsal and ventral areas |
| Q37134856 | Task precision at transfer determines specificity of perceptual learning |
| Q34441693 | The challenges of developing a contrast-based video game for treatment of amblyopia |
| Q46189649 | The functional form of performance improvements in perceptual learning: learning rates and transfer |
| Q39135174 | Treated amblyopes remain deficient in spatial vision: a contrast sensitivity and external noise study |
| Q28300403 | Video games as a tool to train visual skills |
| Q39445009 | Visual Perceptual Learning and Models. |
| Q36098376 | Visual recovery in cortical blindness is limited by high internal noise. |
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