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Function of a fly motion-sensitive neuron matches eye movements during free flight.Insect detection of small targets moving in visual clutterFrom Form to Function: the Ways to Know a NeuronThe contrast sensitivity function of the praying mantis Sphodromantis lineola.Photoreceptor projection reveals heterogeneity of lamina cartridges in the visual system of the Japanese yellow swallowtail butterfly, Papilio xuthus.Texture-defined objects influence responses of blowfly motion-sensitive neurons under natural dynamical conditions.Genes expressed in the adult brain of Drosophila and effects of their mutations on behavior: a survey of transmitter- and second messenger-related genes.Local and global motion preferences in descending neurons of the flyHoneybees as a model for the study of visually guided flight, navigation, and biologically inspired robotics.Organization of local interneurons in optic glomeruli of the dipterous visual system and comparisons with the antennal lobes.Oculomotor control in calliphorid flies: head movements during activation and inhibition of neck motor neurons corroborate neuroanatomical predictions.Descending neurons supplying the neck and flight motor of Diptera: physiological and anatomical characteristics.Ommatidial type-specific interphotoreceptor connections in the lamina of the swallowtail butterfly, Papilio xuthus.'Vector white noise': a technique for mapping the motion receptive fields of direction-selective visual neurons.Chemical neuroanatomy of the fly's movement detection pathway.Descending neurons supplying the neck and flight motor of Diptera: organization and neuroanatomical relationships with visual pathways.Responses of blowfly motion-sensitive neurons to reconstructed optic flow along outdoor flight paths.Visual system of calliphorid flies: motion- and orientation-sensitive visual interneurons supplying dorsal optic glomeruli.Visual system of calliphorid flies: organization of optic glomeruli and their lobula complex efferents.Systematic analysis of the visual projection neurons of Drosophila melanogaster. I. Lobula-specific pathways.Small-field neurons associated with oculomotor control in muscoid flies: cellular organization in the lobula plate.Premotor descending neurons responding selectively to local visual stimuli in flies.Small-field neurons associated with oculomotor and optomotor control in muscoid flies: functional organization.Spectral heterogeneity of honeybee ommatidia.Optic flow estimation on trajectories generated by bio-inspired closed-loop flight.Motion adaptation leads to parsimonious encoding of natural optic flow by blowfly motion vision system.Neuronal basis for parallel visual processing in the fly.Oculomotor control in calliphorid flies: GABAergic organization in heterolateral inhibitory pathways.Synaptic interactions increase optic flow specificity.Neurobiological constraints and fly systematics: how different types of neural characters can contribute to a higher level dipteran phylogeny.Robustness of the tuning of fly visual interneurons to rotatory optic flow.Ca2+ clearance in visual motion-sensitive neurons of the fly studied in vivo by sensory stimulation and UV photolysis of caged Ca2+.Population coding of self-motion: applying bayesian analysis to a population of visual interneurons in the fly.Characterisation of a blowfly male-specific neuron using behaviourally generated visual stimuli.Mechanisms of after-hyperpolarization following activation of fly visual motion-sensitive neurons.
P2860
Q24803040-10A92EFE-6855-4B92-92E2-7D5300341B50Q25255732-4E7031CC-0BB1-49FD-A4CF-BA64ECC6C61EQ29398894-9EDFE5B1-0C86-4CA4-B674-E8DFD95B53B9Q30658584-F99199FC-A5D5-4D41-A432-4FB5325E55C0Q31144900-5AE6C67E-8558-4795-98AC-1F5D70871AEBQ33569324-F02954CF-8AFF-459F-8F75-36787CAA3BADQ36516371-C34CE9E0-A905-48B4-B99C-CFC45F136CCCQ37428772-2EB2ED60-6C2A-49DB-B0F1-828088344707Q37870033-198C84C7-B3F3-4AB5-8F44-B3D8129B4324Q40192061-6D76DB45-6E50-4A2F-B7B6-3E460FC5E036Q40968741-20ABBDA9-D35E-4903-A2C3-789DFE45226DQ41901703-D9ECFBC0-8B11-45AF-92CD-ABE3B4E0DA8EQ42038868-B9D23705-B593-4253-B053-1DFBD98401A0Q42070549-A76178AD-1913-4A83-90BF-05F23EBC89FDQ44675793-E181F0D1-B7D8-4667-ABA2-9426FAC9277EQ45201838-48A39E11-FFF0-49B4-8324-229B98FD7ACAQ46679418-A70429DA-DE67-4C4C-BE17-27A17DA3E665Q48372578-D9B243FA-9D6D-4B39-BC9D-9AFD9B0B9199Q48372585-3877108D-2308-463C-8449-9EACA6A8304EQ48486643-4B5D7903-F4CC-4D95-A183-D767B96866F4Q48536199-424788E6-B101-45EF-AFFD-3FE81F30B06BQ48541827-49581680-D77C-42ED-9582-16D123DCC7F8Q49162723-01202CA4-C017-4C2C-9D59-497BBF8C27F9Q50483187-CDDC4BDD-D7FD-4F66-B63E-DC27A5889364Q51563258-FB05F142-7714-4DF1-AA7F-934D7C358F66Q51633637-D9433C69-E4C0-4FD4-9DE2-4E00A3DF8E84Q52447460-8728CE8E-35BD-488B-95A7-E0395C30A66BQ52546667-0CAF0745-424C-4D5A-A778-87EC76AD0011Q52580491-6701F334-1E8D-48D1-A4FF-1355C1D1547FQ52581569-82F7FC32-5FB5-48EB-8619-F79238FA3C25Q52605840-212C1D22-CD71-428B-818A-6E8D10E96FBAQ52649000-9AF88F95-778F-42B3-9EF3-9114BB2A282DQ52657557-FE01616F-6A02-4944-892F-295CA34608A7Q52677248-AE479B49-9A66-4CED-B145-5BDC1DA97B86Q52698570-8E9F4216-CDD1-4B1C-9691-ACA02CD204EA
P2860
description
wetenschappelijk artikel
@nl
наукова стаття, опублікована в 1989
@uk
name
Neural Mechanisms of Visual Course Control in Insects
@en
Neural Mechanisms of Visual Course Control in Insects
@nl
type
label
Neural Mechanisms of Visual Course Control in Insects
@en
Neural Mechanisms of Visual Course Control in Insects
@nl
prefLabel
Neural Mechanisms of Visual Course Control in Insects
@en
Neural Mechanisms of Visual Course Control in Insects
@nl
P1476
Neural Mechanisms of Visual Course Control in Insects
@en
P2093
Klaus Hausen
Martin Egelhaaf
P304
P356
10.1007/978-3-642-74082-4_18
P577
1989-01-01T00:00:00Z