Anterior inferotemporal neurons of monkeys engaged in object recognition can be highly sensitive to object retinal position.
about
The neural mechanisms for the recognition of face identity in humansSignal propagation in cortical networks: A Digital Signal Processing ApproachTwo Visual Pathways in Primates Based on Sampling of Space: Exploitation and Exploration of Visual Information.Representing where along with what information in a model of a cortical patch.Unsupervised natural visual experience rapidly reshapes size-invariant object representation in inferior temporal cortex.Higher level visual cortex represents retinotopic, not spatiotopic, object locationThe primate amygdala combines information about space and valueInterpreting fMRI data: maps, modules and dimensions.A preference for contralateral stimuli in human object- and face-selective cortex.Multivariate patterns in object-selective cortex dissociate perceptual and physical shape similaritySpatial modulation of primate inferotemporal responses by eye position.The "parahippocampal place area" responds preferentially to high spatial frequencies in humans and monkeys.How cortical neurons help us see: visual recognition in the human brainGrounding word learning in space.High-level visual object representations are constrained by position.Lower-level stimulus features strongly influence responses in the fusiform face areaForgetting what was where: the fragility of object-location binding.Broad and narrow conceptual tuning in the human frontal lobesPosition specificity of adaptation-related face aftereffects.Task-dependent spatial selectivity in the primate amygdala.Neural representation of ambiguous visual objects in the inferior temporal cortexStimulus selectivity in dorsal and ventral prefrontal cortex after training in working memory tasksThe emergent executive: a dynamic field theory of the development of executive function.Optogenetic and pharmacological suppression of spatial clusters of face neurons reveal their causal role in face gender discrimination.Simultaneous shape repulsion and global assimilation in the perception of aspect ratio.A neural circuit basis for spatial working memory.Invariant Visual Object and Face Recognition: Neural and Computational Bases, and a Model, VisNetPosition sensitivity in the visual word form area.Renewing the respect for similarity.The primate working memory networks.Characterizing responses of translation-invariant neurons to natural stimuli: maximally informative invariant dimensions.What and where information in the caudate tail guides saccades to visual objectsShape encoding consistency across colors in primate V4.The distribution of category and location information across object-selective regions in human visual cortexRelating retinotopic and object-selective responses in human lateral occipital cortex.Behavioral Differences in the Upper and Lower Visual Hemifields in Shape and Motion PerceptionMobile computation: spatiotemporal integration of the properties of objects in motionDoes learned shape selectivity in inferior temporal cortex automatically generalize across retinal position?An integrated reweighting theory of perceptual learning.Cortical mechanisms of sensory learning and object recognition.
P2860
Q27009205-649590DD-D383-4D67-96AD-F35257156641Q27500459-E8871D2F-D245-4060-899D-2E2A170B5DB9Q30368407-3CD150CF-B8B3-426D-B74F-B5C8A11C5EF6Q30496622-3E2D5367-C606-49AF-9175-08AEA40B2F4CQ30496776-58D09435-B9A1-49A6-B007-0E2D9C13899AQ30528055-4C00467C-5402-4E47-8F40-8F4CDEFF1B30Q30537548-D9589CE8-872D-4EA3-BFA1-19D2A3E859AFQ31142918-C54560ED-806D-4E9E-95B1-423AADC06FCEQ33288967-5DCAAAAA-9B43-4460-B5A1-05F0083BC141Q33356203-72C86502-D3C6-43E7-84C5-9CA3E62FDE4AQ33378903-74C7C6B4-72E1-4A4D-A552-15B505C30D03Q33869375-53B38221-CD75-479C-8773-D035676CB370Q34090131-2233B18B-D8D2-4C13-A3C6-0438EFC82BEAQ34109945-C90D790C-9786-4C32-92B6-20E7D1DB9052Q34297651-19DB19DB-1C19-4BD5-A18D-3CBFA7CEA869Q34398828-4E66B6A4-FB2B-478B-A175-87E5AA2343FFQ34464855-55FC9DBF-B5BA-4682-87EE-7BBF344F2AF5Q34488134-A5B8E839-1782-4851-8F10-B9D2EA1371CCQ34539221-841B421B-8FD8-49C3-A432-FCE368748506Q34614536-2711675F-6D79-4764-909C-3C3CC750F000Q35009703-27920CF7-620B-478B-9BBD-1D5301563399Q35012893-3B74D107-CD30-488F-815F-D2A2A396AE2CQ35591563-0B1E9C90-DCB7-4E50-B9FE-D4587E5413B7Q35669328-38D5E207-7FD9-441F-83ED-6959F7A6706BQ35682146-EDA160A7-11FD-41A2-ACB0-851F299DD911Q35943571-FCDEF33F-410F-4719-8C9C-1656D657CB16Q36041776-673026F9-393B-4159-B356-9A8F3F35A646Q36066421-BA853F20-B0CF-4B27-9E79-D2CE29B3EF02Q36093765-AAA5AD5E-F615-48E1-AB08-B00B1C73CB7FQ36105446-E8AF7DEF-B809-4F69-86A8-637CC357A1A6Q36137044-32672AB2-DF78-4690-9993-03E0FA5381F9Q36301802-62DF980B-A77D-4FB6-9A67-51715A956FE4Q36532332-7128E96D-6E3F-4BF1-A02D-6290FEB1118BQ36670031-2DAA205E-1746-4BFC-9820-F0FE63E289C6Q36805065-B0AF7FD2-A270-4876-8264-8F014D2A8CF2Q37014485-75A16BD9-2AFD-4351-BE3F-45CD066B00F2Q37034206-518C89AD-EF35-40F6-8E07-FB61E81A8DCEQ37079332-46062A92-A288-4F45-A884-AE6892732071Q37104038-6F1FF5CD-0F07-4B7F-A7DA-2BD3972863CCQ37172603-ECD31762-C65E-4F6A-9321-568A468ED4B8
P2860
Anterior inferotemporal neurons of monkeys engaged in object recognition can be highly sensitive to object retinal position.
description
2003 nî lūn-bûn
@nan
2003年の論文
@ja
2003年学术文章
@wuu
2003年学术文章
@zh-cn
2003年学术文章
@zh-hans
2003年学术文章
@zh-my
2003年学术文章
@zh-sg
2003年學術文章
@yue
2003年學術文章
@zh
2003年學術文章
@zh-hant
name
Anterior inferotemporal neuron ...... ve to object retinal position.
@en
Anterior inferotemporal neuron ...... ve to object retinal position.
@nl
type
label
Anterior inferotemporal neuron ...... ve to object retinal position.
@en
Anterior inferotemporal neuron ...... ve to object retinal position.
@nl
prefLabel
Anterior inferotemporal neuron ...... ve to object retinal position.
@en
Anterior inferotemporal neuron ...... ve to object retinal position.
@nl
P2860
P356
P1476
Anterior inferotemporal neuron ...... ive to object retinal position
@en
P2093
James J DiCarlo
P2860
P304
P356
10.1152/JN.00358.2002
P407
P50
P577
2003-06-01T00:00:00Z