Neural mechanisms for processing binocular information I. Simple cells.
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The accuracy of membrane potential reconstruction based on spiking receptive fields.Spectral mixing of rhythmic neuronal signals in sensory cortex.Sublinear binocular integration preserves orientation selectivity in mouse visual cortex.Delayed suppression shapes disparity selective responses in monkey V1.Effects of generalized pooling on binocular disparity selectivity of neurons in the early visual cortexBinocular neurons in parastriate cortex: interocular 'matching' of receptive field properties, eye dominance and strength of silent suppression"What Not" Detectors Help the Brain See in DepthRapid plasticity of binocular connections in developing monkey visual cortex (V1).Neural computations underlying depth perceptionComputational subunits of visual cortical neurons revealed by artificial neural networks.Modeling V1 disparity tuning to time-varying stimuli.Limits of stereopsis explained by local cross-correlation.Cross-matching: a modified cross-correlation underlying threshold energy model and match-based depth perception.Ocular dominance predicts neither strength nor class of disparity selectivity with random-dot stimuli in primate V1Testing quantitative models of binocular disparity selectivity in primary visual cortexStereoscopic depth perception using a model based on the primary visual cortex.Human stereopsis is not limited by the optics of the well-focused eye.Mapping receptive fields in primary visual cortex.Contrast gain-control in stereo depth and cyclopean contrast perceptionDevelopment of orientation tuning in simple cells of primary visual cortex.Adaptation to natural binocular disparities in primate V1 explained by a generalized energy modelV1 mechanisms underlying chromatic contrast detectionMechanisms underlying the transformation of disparity signals from V1 to V2 in the macaque.Temporal evolution of pattern disparity processing in humansA quantitative explanation of responses to disparity-defined edges in macaque V2.Untuned suppression makes a major contribution to the enhancement of orientation selectivity in macaque v1.Linear and nonlinear systems analysis of the visual system: why does it seem so linear? A review dedicated to the memory of Henk Spekreijse.Strabismus disrupts binocular synaptic integration in primary visual cortex.Terminator disparity contributes to stereo matching for eye movements and perception.The limits of human stereopsis in space and timeOptimal disparity estimation in natural stereo images.Categorically distinct types of receptive fields in early visual cortex.Monofixation with eso-, exo-, or hypertropia: is there a difference?A study on surface slant encoding in V1.Neural noise can explain expansive, power-law nonlinearities in neural response functions.Contributions of excitation and suppression in shaping spatial frequency selectivity of V1 neurons as revealed by binocular measurements.Spatial frequency-specific contrast adaptation originates in the primary visual cortex.Oblique effect: a neural basis in the visual cortex.Clinical features of acute acquired comitant esotropia in the Chinese populations.Accuracy of subspace mapping of spatiotemporal frequency domain visual receptive fields.
P2860
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P2860
Neural mechanisms for processing binocular information I. Simple cells.
description
1999 nî lūn-bûn
@nan
1999年の論文
@ja
1999年論文
@yue
1999年論文
@zh-hant
1999年論文
@zh-hk
1999年論文
@zh-mo
1999年論文
@zh-tw
1999年论文
@wuu
1999年论文
@zh
1999年论文
@zh-cn
name
Neural mechanisms for processing binocular information I. Simple cells.
@en
type
label
Neural mechanisms for processing binocular information I. Simple cells.
@en
prefLabel
Neural mechanisms for processing binocular information I. Simple cells.
@en
P2093
P356
P1476
Neural mechanisms for processing binocular information I. Simple cells.
@en
P2093
P304
P356
10.1152/JN.1999.82.2.891
P407
P577
1999-08-01T00:00:00Z