| scholarly article | Q13442814 |
| P6179 | Dimensions Publication ID | 1021961734 |
| P356 | DOI | 10.1038/NN1556 |
| P3181 | OpenCitations bibliographic resource ID | 512276 |
| P698 | PubMed publication ID | 16286933 |
| P5875 | ResearchGate publication ID | 7481376 |
| P50 | author | Matteo Carandini | Q6789658 |
| P2093 | author name string | Robert A Frazor | |
| Valerio Mante | |||
| Vincent Bonin | |||
| Wilson S Geisler | |||
| P2860 | cites work | The suppressive field of neurons in lateral geniculate nucleus | Q28283428 |
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| Contrast affects the transmission of visual information through the mammalian lateral geniculate nucleus | Q48203247 | ||
| X and Y ganglion cells inform the cat's brain about contrast in the retinal image. | Q48349102 | ||
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| Retinal light adaptation—evidence for a feedback mechanism | Q59064361 | ||
| Adaptation of retinal processing to image contrast and spatial scale | Q59070028 | ||
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| The dynamics of light adaptation in cat horizontal cell responses | Q72836023 | ||
| Spatial properties of the cat X-cell receptive field as a function of mean light level | Q73310017 | ||
| Natural signal statistics and sensory gain control | Q74286770 | ||
| Linearity of cortical receptive fields measured with natural sounds | Q75411918 | ||
| Multiple mechanisms for contrast adaptation in the retina | Q78616554 | ||
| Profound contrast adaptation early in the visual pathway | Q79878214 | ||
| A Simple Coding Procedure Enhances a Neuron's Information Capacity | Q105584836 | ||
| P433 | issue | 12 | |
| P407 | language of work or name | English | Q1860 |
| P304 | page(s) | 1690-7 | |
| P577 | publication date | 2005-12-01 | |
| P1433 | published in | Nature Neuroscience | Q1535359 |
| P1476 | title | Independence of luminance and contrast in natural scenes and in the early visual system | |
| P478 | volume | 8 |
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| Q48665787 | Context-dependent lightness affects perceived contrast. |
| Q64102379 | Contrast and luminance adaptation alter neuronal coding and perception of stimulus orientation |
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| Q38837047 | Contrast response functions in the visual wulst of the alert burrowing owl: a single-unit study |
| Q39463940 | Contrast sensitivity in natural scenes depends on edge as well as spatial frequency structure |
| Q46138682 | Contrast sensitivity is enhanced by expansive nonlinear processing in the lateral geniculate nucleus |
| Q48714860 | Contrast-dependent OFF-dominance in cat primary visual cortex facilitates discrimination of stimuli with natural contrast statistics. |
| Q37105613 | Design of a neuronal array |
| Q47201368 | Design strategies for dynamic closed-loop optogenetic neurocontrol in vivo |
| Q48428863 | Different spatial frequency bands selectively signal for natural image statistics in the early visual system. |
| Q51968768 | Differential detection of global luminance and contrast changes across saccades and flickers during active scene perception. |
| Q46334075 | Distinct expressions of contrast gain control in parallel synaptic pathways converging on a retinal ganglion cell |
| Q28282183 | Do we know what the early visual system does? |
| Q49123745 | Dynamic contrast change produces rapid gain control in visual cortex. |
| Q51878313 | Dynamic spectrotemporal feature selectivity in the auditory midbrain. |
| Q48323445 | Effects of luminance on dynamic random-dot correlogram evoked visual potentials |
| Q33828329 | Effects of mean luminance changes on human contrast perception: contrast dependence, time-course and spatial specificity |
| Q53634410 | Effects of spike-triggered negative feedback on receptive-field properties. |
| Q50567183 | Efficient Neural Codes That Minimize Lp Reconstruction Error. |
| Q30496791 | Efficient temporal processing of naturalistic sounds |
| Q30406818 | Emergence of band-pass filtering through adaptive spiking in the owl's cochlear nucleus |
| Q24629885 | Encoding and decoding cortical representations of tactile features in the vibrissa system |
| Q33757778 | Envelope statistics of self-motion signals experienced by human subjects during everyday activities: Implications for vestibular processing |
| Q100415810 | Evidence for the intrinsically nonlinear nature of receptive fields in vision |
| Q42363812 | Evidence of Asymptomatic Visual Losses after Surgical Repair of Cerebral Aneurysm |
| Q36314627 | Faster thalamocortical processing for dark than light visual targets |
| Q30484733 | Feedforward excitation and inhibition evoke dual modes of firing in the cat's visual thalamus during naturalistic viewing |
| Q34211439 | Feedforward inhibition and synaptic scaling--two sides of the same coin? |
| Q55116398 | Firing-rate based network modeling of the dLGN circuit: Effects of cortical feedback on spatiotemporal response properties of relay cells. |
| Q51905374 | Foveated analysis of image features at fixations. |
| Q36061162 | Frequency Responses of Rat Retinal Ganglion Cells. |
| Q83680790 | From spatial frequency contrast to edge preponderance: the differential modulation of early visual evoked potentials by natural scene stimuli |
| Q37212622 | Functional circuitry of visual adaptation in the retina |
| Q28741612 | Global properties of natural scenes shape local properties of human edge detectors |
| Q30494938 | Heterogeneous response dynamics in retinal ganglion cells: the interplay of predictive coding and adaptation |
| Q46281251 | Image Sharpness and Contrast Tuning in the Early Visual Pathway |
| Q36321759 | In praise of artifice |
| Q30391555 | Incorporating Midbrain Adaptation to Mean Sound Level Improves Models of Auditory Cortical Processing |
| Q51855929 | Independence of color and luminance edges in natural scenes. |
| Q92078730 | Inferring synaptic inputs from spikes with a conductance-based neural encoding model |
| Q37900745 | Inhibitory circuits for visual processing in thalamus |
| Q37354022 | Inter-ocular contrast normalization in human visual cortex |
| Q41038891 | Interocular contrast difference drives illusory 3D percept. |
| Q30580014 | Linking the computational structure of variance adaptation to biophysical mechanisms |
| Q82222778 | Local luminance and contrast in natural images |
| Q30670654 | Melanopsin-driven increases in maintained activity enhance thalamic visual response reliability across a simulated dawn |
| Q37571957 | Modeling lateral geniculate nucleus response with contrast gain control. Part 1: formulation |
| Q84421022 | Modelling the dynamics of motion integration with a new luminance-gated diffusion mechanism |
| Q41073091 | Models of Acetylcholine and Dopamine Signals Differentially Improve Neural Representations |
| Q27438187 | Monocular perceptual learning of contrast detection facilitates binocular combination in adults with anisometropic amblyopia |
| Q60643400 | Movies in the magnet: Naturalistic paradigms in developmental functional neuroimaging |
| Q34621621 | Multiple components of ganglion cell desensitization in response to prosthetic stimulation |
| Q36797437 | Multiple sites of adaptation lead to contrast encoding in the Drosophila olfactory system |
| Q57814920 | Natural Scene Evoked Population Dynamics across Cat Primary Visual Cortex Captured with Voltage-Sensitive Dye Imaging |
| Q57804833 | Natural image and receptive field statistics predict saccade sizes |
| Q37146800 | Natural images dominate in binocular rivalry |
| Q33940940 | Natural images from the birthplace of the human eye. |
| Q48677566 | Natural versus synthetic stimuli for estimating receptive field models: a comparison of predictive robustness. |
| Q50096309 | Naturalness Preserved Image Enhancement Using a priori Multi-Layer Lightness Statistics. |
| Q21559670 | Network connections that evolve to circumvent the inverse optics problem |
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| Q96640239 | Neuronal On- and Off-type heterogeneities improve population coding of envelope signals in the presence of stimulus-induced noise |
| Q41192374 | Neurons in primary visual cortex represent distribution of luminance |
| Q30459714 | Neurons in the thalamic reticular nucleus are selective for diverse and complex visual features |
| Q30426061 | Nonlinear temporal receptive fields of neurons in the dorsal cochlear nucleus. |
| Q28253709 | Normalization as a canonical neural computation |
| Q39451252 | Orientation selectivity in rat primary visual cortex emerges earlier with low-contrast and high-luminance stimuli |
| Q27312200 | Orientation-cue invariant population responses to contrast-modulated and phase-reversed contour stimuli in macaque V1 and V2 |
| Q30404940 | Parallel coding of first- and second-order stimulus attributes by midbrain electrosensory neurons. |
| Q42352750 | Perceived Duration Increases with Contrast, but Only a Little |
| Q39994338 | Perceived blur in naturally contoured images depends on phase |
| Q30541914 | Peri-saccadic natural vision. |
| Q48350386 | Population response to natural images in the primary visual cortex encodes local stimulus attributes and perceptual processing. |
| Q30454689 | Pre-attentive, context-specific representation of fear memory in the auditory cortex of rat |
| Q35644738 | Predicting cortical dark/bright asymmetries from natural image statistics and early visual transforms |
| Q27318762 | Push-Pull Receptive Field Organization and Synaptic Depression: Mechanisms for Reliably Encoding Naturalistic Stimuli in V1. |
| Q39757170 | Quantifying "the aperture problem" for judgments of motion direction in natural scenes |
| Q30525509 | Quantifying utricular stimulation during natural behavior |
| Q38986369 | Rapid Sensory Adaptation Redux: A Circuit Perspective |
| Q31036963 | Rapid dynamics of contrast responses in the cat primary visual cortex |
| Q33811683 | Rebalancing binocular vision in amblyopia |
| Q50455529 | Receptive field for dorsal cochlear nucleus neurons at multiple sound levels. |
| Q48171890 | Responses of neurons in primary visual cortex to transient changes in local contrast and luminance. |
| Q40669322 | Restoration of Vision with Ectopic Expression of Human Rod Opsin |
| Q42122415 | Retinal ganglion cell adaptation to small luminance fluctuations |
| Q46085877 | Rods progressively escape saturation to drive visual responses in daylight conditions. |
| Q39171015 | SK channel subtypes enable parallel optimized coding of behaviorally relevant stimulus attributes: A review |
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| Q37209789 | Seeing the invisible: the scope and limits of unconscious processing in binocular rivalry |
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| Q34666602 | Sensory adaptation |
| Q48346361 | Separate spatial and temporal frequency tuning to visual motion in human MT+ measured with ECoG. |
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| Q47248569 | Simultaneous contrast and gamut relativity in achromatic color perception |
| Q36948392 | Sparsely distributed contours dominate extra-striate responses to complex scenes. |
| Q35104429 | Spatial filtering versus anchoring accounts of brightness/lightness perception in staircase and simultaneous brightness/lightness contrast stimuli |
| Q45953984 | Spatial frequency-specific contrast adaptation originates in the primary visual cortex. |
| Q28729137 | Speed, sensitivity, and stability of the light response in rod and cone photoreceptors: facts and models |
| Q30405256 | Spike-Triggered Covariance Analysis Reveals Phenomenological Diversity of Contrast Adaptation in the Retina |
| Q48583325 | Spillmann's weaves are more resilient than Hermann's grid. |
| Q38713124 | Statistics of natural scenes and cortical color processing |
| Q36564553 | Temporal Asymmetry in Dark-Bright Processing Initiates Propagating Activity across Primary Visual Cortex. |
| Q49911927 | Temporal structure in spiking patterns of ganglion cells defines perceptual thresholds in rodents with subretinal prosthesis. |
| Q38611168 | The Divisive-Normalization Model of V1 Neurons: A Comprehensive Comparison of Physiological Data and Model Predictions. |
| Q89260021 | The dynamic receptive fields of retinal ganglion cells |
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| Q37017235 | The response of retinal neurons to high-frequency stimulation. |
| Q46083005 | The statistical computation underlying contrast gain control. |
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| Q37462001 | Transient covert attention does alter appearance: a reply to Schneider (2006). |
| Q36346233 | V1 neurons respond to luminance changes faster than contrast changes |
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| Q41969866 | Voluntary attention enhances contrast appearance |
| Q38796357 | Why is Binocular Rivalry Uncommon? Discrepant Monocular Images in the Real World |
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