Sensory Systems and Flight Stability: What do Insects Measure and Why?
about
Aerodynamics, sensing and control of insect-scale flapping-wing flightMotion as a source of environmental information: a fresh view on biological motion computation by insect brainsWireless stimulation of antennal muscles in freely flying hawkmoths leads to flight path changesProprioceptive feedback determines visuomotor gain in DrosophilaHoneybees' speed depends on dorsal as well as lateral, ventral and frontal optic flowsBiomechanics and biomimetics in insect-inspired flight systemsActive and passive stabilization of body pitch in insect flightTowards a biomimetic gyroscope inspired by the fly's haltere using microelectromechanical systems technology.Discovering the flight autostabilizer of fruit flies by inducing aerial stumbles.Vision and air flow combine to streamline flying honeybees.Stable hovering of a jellyfish-like flying machine.Orientation cues for high-flying nocturnal insect migrants: do turbulence-induced temperature and velocity fluctuations indicate the mean wind flow?Predicting fruit fly's sensing rate with insect flight simulations.A three-dimensional atlas of the honeybee neck.Depth information in natural environments derived from optic flow by insect motion detection system: a model analysis.Impact of stride-coupled gaze shifts of walking blowflies on the neuronal representation of visual targetsControlled flight of a biologically inspired, insect-scale robot.Temporal statistics of natural image sequences generated by movements with insect flight characteristics.Science, technology and the future of small autonomous drones.Flight control and landing precision in the nocturnal bee Megalopta is robust to large changes in light intensityInsect-Inspired Self-Motion Estimation with Dense Flow Fields--An Adaptive Matched Filter Approach.Scene perception and the visual control of travel direction in navigating wood antsA new navigational mechanism mediated by ant ocelli.Neural control and precision of flight muscle activation in Drosophila.Bio-inspired modeling and implementation of the ocelli visual system of flying insects.Wing-pitch modulation in maneuvering fruit flies is explained by an interplay between aerodynamics and a torsional spring.Visual input and path stabilization in walking ants.Integration of binocular optic flow in cervical neck motor neurons of the fly.Adaptive control of turbulence intensity is accelerated by frugal flow sampling.Effects of different animal manures on attraction and reproductive behaviors of common house fly, Musca domestica L.Can body traits, other than wings, reflect the flight ability of Triatominae bugs?Pigeons (C. livia) Follow Their Head during Turning Flight: Head Stabilization Underlies the Visual Control of Flight.Four of the six Drosophila rhodopsin-expressing photoreceptors can mediate circadian entrainment in low light.Functional role of airflow-sensing hairs on the bat wing.Head movements quadruple the range of speeds encoded by the insect motion vision system in hawkmoths.Intrinsic stability of a body hovering in an oscillating airflow.Elytra reduction may affect the evolution of beetle hind wings.Neural evidence supports a dual sensory-motor role for insect wings.
P2860
Q26749464-87A4A3A2-8739-4649-90D3-3E5198B3FD7BQ27026832-DACDD07F-A86E-45A7-98D7-42C6DE3BDD99Q27324173-9BA532F6-7E96-41C7-A51F-DBA6B7EE1B1AQ27334894-D28A7913-3152-40B3-926C-99DFAC0B3B0CQ27343022-E533C0C9-5AA3-41FC-B6E9-B9963BE26387Q28077115-C953FF08-761E-4184-8DBF-6A7F787A7F3CQ28658882-7BBFDAA5-8F7D-48D5-98D8-59643FC58B6BQ30401472-8946EA25-68FA-4D27-A39A-7B65701D1B79Q30493792-B2DB9E82-F494-49A2-9E5F-70AEFDC98165Q30544340-8E14735E-05BB-4064-B717-16DA9AF1F920Q30567162-41849189-A31E-42C7-BAE6-5EB105BA99B5Q30994875-06F1964E-0AD6-4A23-9599-10F28EBE0C25Q33358792-EB341919-5D7A-40D3-818F-23076FCB36F1Q33592875-503D9C2D-18B0-4698-AC11-F6F783BF4D4AQ33984925-E8496FF4-4F65-4F12-8275-333AFA65E35EQ34180850-ED6ABE40-E361-492B-AAD7-1F5D47EB81B7Q34342741-78311559-2F8E-4914-8256-FE46110BF9B2Q34395487-DAF30096-4095-4203-94B5-3ADDADA59D2BQ34478147-B8C57F25-DF17-42A4-AB74-7C211F14A4BFQ34502065-41064F19-4967-4349-8631-B9AFEA398F33Q35756022-E6C435A2-7F1D-4456-BD7B-61EE5B599939Q38176335-5789318F-7DE9-46CB-BBFD-434F619FCB70Q38568600-DAABEEAC-347F-4D05-AC08-FBEBD000C849Q39036073-6C84D089-0F81-4FD8-8021-FD5B83B96E14Q40221947-DB45A19C-5F3E-418B-AC4F-B85A704D47A6Q40526945-951EA0F2-6B01-4AD8-9CB2-17DA3B065EB7Q41954927-004AFCB5-3658-4C26-B26E-14B44E6D2C99Q45004258-D33DF390-1E18-4C46-9735-01E539DE2586Q45072364-FA89791E-6191-4A30-AD57-9E3BD8547F9BQ46545118-E428A694-DFC6-4C73-8707-35BC68479C66Q46622873-866FECAF-7A0A-4C5D-9A6E-FFEA593E49B1Q47118788-7282025A-6F91-4442-B7D5-C262C5B0F0D9Q47877565-5A9F82DF-A05A-4753-AB09-5EB3F9550F88Q48428111-8C138661-7B8F-492C-9807-836A812E81ECQ51175172-787A6795-BF75-469B-BD37-9B55EC33A239Q51406626-FF813C9C-3E52-4DE7-A3EA-D3C3AFB26653Q51736325-B1F7BBC3-A7BF-4B29-A942-764F4454786AQ51791042-7E73C000-DEC4-40A1-9B76-DC637AEA6974
P2860
Sensory Systems and Flight Stability: What do Insects Measure and Why?
description
wetenschappelijk artikel
@nl
наукова стаття, опублікована у 2007
@uk
name
Sensory Systems and Flight Stability: What do Insects Measure and Why?
@en
Sensory Systems and Flight Stability: What do Insects Measure and Why?
@nl
type
label
Sensory Systems and Flight Stability: What do Insects Measure and Why?
@en
Sensory Systems and Flight Stability: What do Insects Measure and Why?
@nl
prefLabel
Sensory Systems and Flight Stability: What do Insects Measure and Why?
@en
Sensory Systems and Flight Stability: What do Insects Measure and Why?
@nl
P1476
Sensory Systems and Flight Stability: What do Insects Measure and Why?
@en
P2093
Graham K. Taylor
Holger G. Krapp
P304
P356
10.1016/S0065-2806(07)34005-8
P577
2007-01-01T00:00:00Z