Super slow-motion footage of a moth in flight has revealed how the insects use their bodies to hover.
The moth moves its body by pivoting its abdomen up and down to fine-tune the forces that keep the insect airborne.
The researchers are studying insect flight in order to "distil the biological principles of flight control".
This, they say, will help them to accurately engineer flying robots that use these same principles.
Their insights, which show how the insects use more than just their wings as they control their flight, are published in the Journal of Experimental Biology.
Continue reading the main storyFlapping and flying
As an insect's wings move through the air, they are held at a slight angle, which de?ects the air downward.
This deflection means the air flows faster over the wing than underneath, causing air pressure to build up beneath the wings, while the pressure above the wings is reduced. It is this di?erence in pressure that produces lift.
Flapping creates an additional forward and upward force known as thrust, which counteracts the insect's weight and the "drag" of air resistance.
The downstroke or the flap is also called the "power stroke", as it provides the majority of the thrust. During this, the wing is angled downwards even more steeply.
You can imagine this stroke as a very brief downward dive through the air - it momentarily uses the weight of the animal's own weight in order to move forwards. But because the wings continue to generate lift, the creature remains airborne.
In each upstroke, the wing is slightly folded inwards to reduce resistance.
Lead author Jonathan Dyhr from University of Washington explained that - in terms of insect models - moths provided a particularly interesting basis for miniaturised robots.
"They're larger insects, so they're in a more realistic range of flapping or flying [machines that we would be] able to put instrumentation on.
And although they're relatively big, Dr Dyhr explained, they're "incredibly good at hovering."
"A moth can really precisely control movements [and remain] in one place, because it's trying to feed from flowers," he said.
To find out how the insects managed this feat, the team put a moth into a kind of tiny flight simulator.
The scientists tethered the moth inside an arena that simulated the environment around the insect moving up and down. With this simulation, the scientists were able to make the insect perceive that it was rising or sinking.
In response to this movement, as the super slow-motion footage revealed, the insect pivoted its abdomen up and down.
"If it started pitching up," Dr Dhyr explained, "it would move its abdomen up, and that will cause its centre of mass to change."
This adjusted the airflow to the insect's wings, in turn adjusting the lift and thrust that the wings produced. These are the forces that keep the insect airborne and moving forwards (see right).
By changing the angle of their wings and their body, the moth was able to create a delicate balance between the thrust pushing it forwards, the drag - or air resistance - pushing against it, and the lift keeping it in the air.
It is these finely tuned movements that keep the flying insects in one spot - hovering above a flower as they feed from it.
Dr Dhyr said it was "really rewarding" to answer this fundamental question.
He told BBC News: "We got to collaborate with engineers and use really unique methods to answer very basic biological question."
Source: http://www.bbc.co.uk/news/science-environment-22130854#sa-ns_mchannel=rss&ns_source=PublicRSS20-sa
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