Performance trade-offs in the flight initiation of Drosophila.
about
Estimating Orientation of Flying Fruit FliesBehavioral responses to a repetitive visual threat stimulus express a persistent state of defensive arousal in DrosophilaAutomated measurement of mouse social behaviors using depth sensing, video tracking, and machine learning.Biomechanics and biomimetics in insect-inspired flight systemsA tyramine-gated chloride channel coordinates distinct motor programs of a Caenorhabditis elegans escape responseObject preference by walking fruit flies, Drosophila melanogaster, is mediated by vision and graviperception.A large-scale behavioral screen to identify neurons controlling motor programs in the Drosophila brain.A novel neuronal pathway for visually guided escape in Drosophila melanogaster.The mechanical properties of Drosophila jump muscle expressing wild-type and embryonic Myosin isoforms.Frequency response of lift control in DrosophilaFlying Drosophila stabilize their vision-based velocity controller by sensing wind with their antennae.How insect flight steering muscles work.The roles of troponin C isoforms in the mechanical function of Drosophila indirect flight muscleComputational Aerodynamic Analysis of a Micro-CT Based Bio-Realistic Fruit Fly Wing.Loom-sensitive neurons link computation to action in the Drosophila visual system.Aerodynamic Ground Effect in Fruitfly Sized Insect Takeoff.Decision Making and Behavioral Choice during Predator Avoidance.The neuroethology of C. elegans escape.Generation of the pitch moment during the controlled flight after takeoff of fruitflies.Optogenetic stimulation of escape behavior in Drosophila melanogaster.An embryonic myosin isoform enables stretch activation and cyclical power in Drosophila jump muscleWing and body motion and aerodynamic and leg forces during take-off in dronefliesEmergence of Selectivity to Looming Stimuli in a Spiking Network Model of the Optic Tectum.Figure-ground discrimination behavior in Drosophila. I. Spatial organization of wing-steering responses.Figure-ground discrimination behavior in Drosophila. II. Visual influences on head movement behavior.Visual projection neurons in the Drosophila lobula link feature detection to distinct behavioral programs.A homozygous FITM2 mutation causes a deafness-dystonia syndrome with motor regression and signs of ichthyosis and sensory neuropathy.Neural circuits that drive startle behavior, with a focus on the Mauthner cells and spiral fiber neurons of fishes.The Role of Motion Extrapolation in Amphibian Prey Capture.Neuromechanical simulation.Activation, orientation and landing of female Culex quinquefasciatus in response to carbon dioxide and odour from human feet: 3-D flight analysis in a wind tunnel.Escaping blood-fed malaria mosquitoes minimize tactile detection without compromising on take-off speed.A spike-timing mechanism for action selection.Whole-body 3D kinematics of bird take-off: key role of the legs to propel the trunk.Experimental and Numerical Investigation on Dragonfly Wing and Body Motion during Voluntary Take-off.Neuron hemilineages provide the functional ground plan for the Drosophila ventral nervous system.The functional organization of descending sensory-motor pathways in Drosophila.Speed dependent descending control of freezing behavior in Drosophila melanogasterDoes Cognition Have a Role in Plasticity of "Innate Behavior"? A Perspective From
P2860
Q27303105-595A7764-877D-489B-9FC9-B86AD157A0ABQ27316226-2CA20167-E4C1-44C0-9677-6C10C6F95ECFQ27318550-E2E36B84-4426-43D0-9EA6-EB61FC6DAC1DQ28077115-D61CA8A9-50A3-4183-8A80-EE16E64751CBQ30492719-156469F0-DCD2-4843-861B-CEB9860FD248Q30495136-7F8A92A4-B9ED-4EDD-A8D4-058AC3D390EAQ30548049-2ECD8952-88A1-4040-8EA6-41E4D29FE2B0Q30556751-CFC2AC6A-0836-4E47-B108-94E39196672DQ33767768-C146F320-C393-481F-9B6C-C119C8318D84Q34333221-64D9BBF1-CBD7-484C-9DBA-00E21202527DQ34410641-1AF90EC5-F51A-47ED-B266-182686111D89Q34411998-2467D87F-BFF2-4E6E-B901-14E480399DD9Q34517038-23B76583-370B-485B-8A7B-E9B05BB95E78Q35625119-4DCFDDC4-BC7F-432C-A743-EEBADD29869DQ35818692-FA3124C3-83B5-4E77-9E88-FC4C9B3B373CQ35971550-FD10E4A5-C13B-4F4B-B12B-02C7E60997F4Q36192316-A6147226-8920-4D87-B8D3-8EC45BA167D3Q36219774-9FE38010-E5F6-4DE8-9A66-ED61ECC40559Q36308985-348DC2DC-5DFA-4E23-B7D4-2E85865273FFQ36639448-B8AD3837-9AB4-4E78-BF7E-777D5B414940Q36939734-C4035936-D4A5-48C2-985B-BD631C73FECAQ37255823-60608651-B755-4191-8B0B-FA1CF1B1FC06Q37433817-4C408249-27E4-43AA-A8CE-997D86A2909FQ37581044-953E241C-EA0F-421F-8A48-7C783BFD87E4Q37581047-E3C18923-71A0-4149-826E-6A02ABB56469Q37626721-BCD6EFCE-BC59-45EA-AEA6-95ECB7D6C666Q37644432-D7FFBB9C-F444-4BE5-AE05-E9CA5BA6F560Q38865508-B107A168-12A9-4859-AF0D-15443E1689B8Q38940866-47AD3CDB-43E7-424C-9838-85E6A27E73D1Q42592094-F11E3BC9-C567-44CD-A0C1-B83B9EC63D8CQ44155552-22208157-2C87-433B-B14E-8204D17E2ACBQ44169205-A6CC73C6-B9A8-49C0-885D-07778F45001FQ44999096-E20649F6-0068-4276-81F8-EB0130DC2A3FQ48250805-069C8705-7CBD-4D96-9835-677463D88CF6Q49329564-41FB2A26-7909-4595-9730-F68AD975E83EQ50576951-8DA64AF7-15CF-4866-A5CA-FD0EA0F0802EQ55413531-06BE147C-60D4-450F-B2FC-E4C5B5488BB2Q58747547-656D190A-3BAB-4392-B337-24FF3A3706D9Q58780796-CD15ED4A-1FC1-4C8D-A5B5-91CCBAE9C196
P2860
Performance trade-offs in the flight initiation of Drosophila.
description
2008 nî lūn-bûn
@nan
2008年の論文
@ja
2008年学术文章
@wuu
2008年学术文章
@zh
2008年学术文章
@zh-cn
2008年学术文章
@zh-hans
2008年学术文章
@zh-my
2008年学术文章
@zh-sg
2008年學術文章
@yue
2008年學術文章
@zh-hant
name
Performance trade-offs in the flight initiation of Drosophila.
@en
Performance trade-offs in the flight initiation of Drosophila.
@nl
type
label
Performance trade-offs in the flight initiation of Drosophila.
@en
Performance trade-offs in the flight initiation of Drosophila.
@nl
prefLabel
Performance trade-offs in the flight initiation of Drosophila.
@en
Performance trade-offs in the flight initiation of Drosophila.
@nl
P356
P1476
Performance trade-offs in the flight initiation of Drosophila.
@en
P2093
Gwyneth Card
Michael Dickinson
P304
P356
10.1242/JEB.012682
P577
2008-02-01T00:00:00Z