Birds Give a Lesson to Plane Designers 250
Roland Piquepaille points out a news release from the University of Michigan where researchers are looking to birds and bats for insights into aerospace engineering. Wei Shyy and his colleagues are learning from solutions developed by nature and applying them to the technology of flight. A presentation on this topic was also given at the 2005 TED conference. From the news release:
"The roll rate of the aerobatic A-4 Skyhawk plane is about 720 degrees per second. The roll rate of a barn swallow exceeds 5,000 degrees per second. Select military aircraft can withstand gravitational forces of 8-10 G. Many birds routinely experience positive G-forces greater than 10 G and up to 14 G. Flapping flight is inherently unsteady, but that's why it works so well. Birds, bats and insects fly in a messy environment full of gusts traveling at speeds similar to their own. Yet they can react almost instantaneously and adapt with their flexible wings."
It's the people, not the planes. (Score:5, Insightful)
Re:It's the people, not the planes. (Score:5, Funny)
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"Have Blue was not inherently stable in flight and would tumble out of control. But fortunately, computers also rendered this fact irrelevant, because aircraft designers for several years had been designing planes, like the F-16 fighter, that were kept stable by computers that constantly adjusted their flight controls in t
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should be doable with computing powerr alone...
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(But still, what about the passengers?)
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That is an assumption (belief). We don't know that. If something is truly random, it is possible to get all variables right in the first try. All the random variables could be just so, to get a fantastically performing airplane.
Re:It's the people, not the planes. (Score:5, Funny)
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It takes far, far fewer generations to get very good results than people's intuition suggests.
Re:It's the people, not the planes. (Score:5, Insightful)
This is something people at universities mess about all the time. I've seen programs about something like this on the science channel or whatever years ago. They had little artificial insects or small birds with cameras on them flying around. Wasn't there news story about them being used by the police to film some demonstrations last year? For reasons known only to himself, Roland decided to pick this particular random news release and make it sound as if its some important new breakthrough when its nothing of the sort.
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Missing tag. (Score:5, Insightful)
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Re:Missing tag. (Score:5, Interesting)
Re:Missing tag. (Score:5, Funny)
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Re:Missing tag. (Score:5, Funny)
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[gets thrown off into the depths of the Bridge of Death]
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As your size increases, your mass quickly outstrips the ability of your muscles and bones to sustain it.
Interestingly, as your size decreases, it works the other way. Mass decreases at a cubic rate and strength [muscles/bones] decreases at a square rate. You become relatively much stronger.
Gerbils can survive falls from any height, elephants b
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Other than the pilot, the next big limit on a plane is "how much stress can the wings take before ripping off." Flexible/shape changing wings would change that significantly.
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Mass of a sparrow at takeoff: ~10g
The fact that one maneuvers faster than the other, it's just... inexplicable.
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Re:Missing tag. (Score:5, Funny)
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Re:Multiple coconuts (Score:4, Funny)
Guess what those "inert bombs" were
[oh, and to answer your question: empty weight is about 11000 lbs; max takeoff weight is 24500 lbs.]
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I believe the meme you are looking for is: "inconceivable".
Re:Missing tag. (Score:5, Insightful)
No one.
Why not?
No.
Irrelevant.
The weather is most probably quite similar since they travel at the same time each year.
If it was longer, it would carry more fat, and vice versa.
They learnt to fly in flocks long before they started to do crazy 2500 mile migrations.
Again, no. The first flocks that set out at random either end up in the ocean, or find land. Those that find land will do this because they had enough food to do this. If each bird in the flock that found land had a random amount of fat, half of them would drop to the ocean, but half would arrive and breed. They would get kids that had genes that would make them eat a little bit more than the imaginary kids from the birds that died. Now repeat for millions of generations, and you'll end up with something quite optimized.
Re:Missing tag. (Score:4, Informative)
All very true, but you missed the fact that when they started out, Hawaii and Alaska were closer. Today's Hawaiian Islands are the end of a long chain of seamounts that stretch out nearly to the Aleutians, with the seamounts getting older as you go northwest. We don't know when those plovers started this migration, but it was some millions of years in the past, when the end of the Hawaiian chain was one of those older seamounts that was then an island. It could have even been back when the islands were barely offshore from the then supercontinent of Laurasia (though it should be mentioned that we don't know this).
So their ancestors that started this migration had an easier job of it. As the islands slowly drifted out to sea, each generation would be selected for the survivors that were able to make a slightly longer flight.
Environmental change, in this case the effect of a moving geological "hot spot", must be taken into account to fully explain a lot of evolutionary events. That's one way you can get results that seem impossible in today's world, especially things like the colonization of remote islands like Hawaii by species that can't cross the open ocean.
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You sentence it contradictory. First you state we don't know and then you say we do know that it was millions of years in the past.
So where's the contradiction? We don't know exactly when they started, but we know it wasn't last year. It could have been at any point in the history of the Emperor Seamount / Hawaiian island chain, which extends back quite a few million years. But since we have no
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I present an alternate hypothesis: millions of Plover's set out for some distant island. Some made it, millions perished. Those that made it had chicks which inherited the distinction. Lather, rinse, repeat until all surviving Plovers are also part of the same group that goes to the same island every year. Natural selection would tend to automatically "tune" the animal to have a specific amount of fat, as
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Re:Missing tag. (Score:5, Informative)
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Where's the "ohnoitsroland" meta tag? :) Seriously, though...
The roll rate of the aerobatic A-4 Skyhawk plane is about 720 degrees per second. The roll rate of a barn swallow exceeds 5,000 degrees per second.
I'm no physics buff, but doesn't this have something to do with the greatly diminished surface area and related physical stresses on the swallow? Anyone with some aeronautics background care to help me out?
Presumably the swallow folds or at least partly folds its wings when performing such manoeuvres. I suppose they'd like the planed to do the same (although getting materials to react fast enough at that scale would be challenging).
Re:Missing tag. (Score:5, Informative)
Apparently once upon a time all articles submitted by Roland linked to his blog which linked to the real article (as a way to generate ad revenue, I think). And he continues to take flak for it to this day.
Like I said, this is second-hand from earlier discussions. I was not here when it was happening.
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If you haven't noticed, today's also a rather slow news day. If you're not interested in politics*, gaming, or cell phones, there are precious few
(That's not to say that politics aren't important, especially now. However, political discussions definitely seem to be dominating slashdot these days)
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Oxford [oed.com] and Webster [merriam-webster.com] both agree with me.
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He also has an annoying habit of misunderstanding the original article, or misrepresenting it with disproportionate claims. You know, some scientist calculates that it might be possible, given conditions X Y Z and eating only lettuce, to extend the average human lifespan by 30 years would be posted as "Immortality no longer a dream".
Oh, and he's French.
laden or unladen? (Score:5, Funny)
Re:laden or unladen? (Score:5, Funny)
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Re:laden or unladen? (Score:5, Funny)
Just now? (Score:2, Insightful)
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In other news... (Score:5, Funny)
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Well, they could sing much better, for a start.
What an uppity prick you are.
Hey, Nemo... (Score:2)
Looking to nature for ideas isn't exactly a lightbulb moment normally associated with professionals. 5th graders, maybe. Thus your comment, right?
Sub designers, aircraft...cars...chairs...these guys/gals are supposed to have studied things like fish, birds, trees and insects for reasons why, and why not, long before they were hired to actually build things.
Re:Hey, Nemo... (Score:4, Insightful)
True, but it might be noted that we made very little progress in flying until some people gave up on trying to mimic birds, and tried other approaches. The first actual "flight" by humans was in the early 1800s, with hotter-than-air balloons. Then around 1900, a few experimenters started to get the hang of wings, and figured out that what worked was to separate the lift generation from the propulsion. Nature never came up with this scheme, but it's technically easier (if you know how to make a rotary motor or a jet engine) than nature's scheme of using wings for both functions.
Similarly, submarines look superficially like fish, but don't really work the same way. Fish use their fins for both steering and propulsion, while submarines use fins only for steering, with a propeller for propulsion. The similar shapes are only for streamlining, which does work the same for everything that needs it.
Usually, nature's solutions to problems are good models. But in cases like fish and birds, it has turned out to work better to give up on them and work from first principles. We're only now starting to produce machines that fly and swim like birds and fish, and they are little more than toys. Our non-natural solutions have turned out to work better for our purposes than what nature found.
We might also note that nature did discover a rotary motor, in the form of bacterial flagellae. We even have them in some of our cells. (Trivia question: Which cells are those?) But nature never figured out how to adapt them to larger, multi-cellular organisms. Maybe on some other planet, but not on this one. Nature also discovered jet propulsion, and uses it under water but not in the air. We know how to do both of these things on a larger scale, and we have used them to solve problems in ways that the evolutionary process hasn't found.
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OTOH, as others have pointed out, what we want from our flying machines is a lot different from what birds want. We have relatively little interest in machines that can incubate eggs, land on tree branches, and communicate by singing. Birds have little interest in carrying hundreds
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You're right, of course. And sails work the same way; they're really just an airfoil turned on end to produce horizontal "lift". This is part of the conventional explanation ("Sailing for Dummies") of why it is that a sailboat's highest speed is at right angles to the wind.
And it's also fun to explain to people with no understanding of such things that penguins wings really function the same as other birds'
Arrakis (Score:5, Funny)
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No... (Score:2)
Ah, sorry, wrong geek-culture.
Cool idea! (Score:5, Funny)
(...and what if you're allergic to feathers? )
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well don't fly on a window then
Birds and insects are puny (Score:5, Insightful)
Birds and insects have very low mass. As mass increases components have deal with more stress etc.
Post another annoying stupid Roland article when birds flying at high speeds weigh as much as an aircraft (or even a human) and then we'll see how they handle things.
Btw, I could have sworn i saw the "ohnoitsroland" tag and then it disappeared
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Shyy is the Clarence L. "Kelly" Johnson Collegiate Professor of Aerospace Engineering. Other authors of the book, "Aerodynamics of Low Reynolds Number Flyers" are: U-M research scientists Yongsheng Lian, Jian Tang and Dragos Viieru, and Hao Liu, professor of Biomechanical Engineering at Chiba University in Japan. Other collaborators on this research include professors Luis Bernal, Carlos Cesnik and Peretz Friedmann of the University of Michigan; Hao L
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Anyhow, comment on the story and not the submitter. Or maybe just shut the hell up? If people stop complaining about shitty stories, then the shitty stories will no longer be published since it will no longer generate the clicks used to complain about the shitty story!
pfftt... (Score:2)
And the problem with making a machine similarly perform is.....?
Didn't Da Vinci study birds? How is this news? Oh, wait...RP needs the ad revenue, of course.
Taken us this long? (Score:3, Insightful)
Perhaps they can roll that fast, and take that many G's, because that's what they have done for thousands (if not millions?) of years. Their bodies have adapted to it, as they do it almost 24/7.
And haven't we already used bernoulli's principle watching birds, and applied that to planes, getting us in the air in the first place. Has it really taken us this long to realize that we can learn how to fly better from watching the things that fly naturally every day?
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Swallows (Score:5, Funny)
Coconut Migration (Score:3, Funny)
A Skyhawk, on the other hand, could carry a large number of coconuts. However, unlike with the swallows (where the main issue is not the grip but the weight ratios), the Skyhawk would be limited by the number of coconuts that could be attached. The Skyhawk is an attack aircraft with a payload of close to 10,000 lbs, which would make for a lot of coconuts. But, the only reasonable place to attach large numbers of them without causing aerodynamic interference would be the wing pylons, where the bombs usually go. If they were to fit, these coconut packages could not be much bigger than the bombs. As there are only five hardpoints, I can't imagine there being room for more than about 50 coconuts.
Still, this is a significant improvement over the swallows, and if you had to choose between the two, the Skyhawk would be a much better choice for migrating coconuts into temperate climes. Of course, something like a C-17 would be even better, but those have an even lower roll rate.
huh... (Score:2)
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Oh, no, Roland the Plogger is back (Score:5, Insightful)
Sometimes they come back.
Roland is off in bogosity land, as usual. The wingspan of a barn swallow is about 0.3m. The wingspan of an A-4 Skyhawk is 8.1m, which is 27x larger. So, scaled for size, an A-4 Skyhawk actually has about 4x the roll rate of a sparrow.
Historically, aircraft that looked or worked like birds have been spectacularly unsuccessful. Little ornithopter UAVs do work, but the ornithopter concept does not scale up well.
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You mean aircraft that have wings (sort of like birds do)?
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Researchers give a lesson to Birds... (Score:2, Funny)
Young Researcher Linked Owls to Airplanes (Score:5, Interesting)
Airplane designers then took that idea and applied it to most commercial jets you see today.
Size?? (Score:2, Insightful)
I mean, what about the maximum load that the material can withstand?
An RC helicopter like a T-Rex 450 may run its main rotor (diameter of 70 cm == 28 inch) at 3000 rpm. Try that with a blackhawk helicopter, the wingtips of the main rotor blades would go faster than 9000 km/h (about 5600 mph), several times the speed of sound, and certainly more than the material could ever withstand...
Ohhh here we go again... (Score:5, Interesting)
This is really amusing, but least I laugh to hard allow me to enlighten some...
The mighty Peregrine Falcon, THE fastest animal in the skies, bar none, have been clocked in dives exceeding 200mph, with radar. Now that is pretty damn fast for anything made of bone, muscle and sinew and covered in something as delicate as feathers. But one has to examine the actions of the animal when it accomplishes these seemingly impossible feats of speed.
Fist of all, much like the famous ( or infamous depending on your POV, especially if you were a pilot in the early very underpowered versions ) F-14 Tomcat Naval Jet Fighter, it makes maximum use of variable wing geometry. When a Peregrine stoops ( the technical term for diving from altitude in the bird world ) its 39 to 43 inch wings fold in very tightly making the outline of the bird look pretty like a "W", leaving just enough airfoil hanging out to effect control. This reduces stress on the main wing spar ( their bones and joints ) by a huge margin thus allowing it to accomplish this feat without tearing its wings off.
Now I don't have an actual measurement of their wing span in a full speed stoop, but from photo's I estimate that it reduces wing span by a good 75% or more. The area of the wing that would comprise the distance between a human elbow and the tips of our fingers goes parallel to the body and the upper wing ( the area from a human shoulder to the elbow ) then are pulled in close to the head, further reducing wing span.
Transition from this "clean" configuration to a "Dirty" configuration after either missing or hitting its prey can be quite rapid and causes the bird to bleed off speed at a very high rate. A Falcon cannot make a "pylon" ( a turn in an airplane in which one rolls the airplane from straight and level flight by nearly 90 degrees and then applies maximum UP elevator ) turn, the force on the wings would quickly overcome the bone, tendon, muscle and joint strength. Now this is not to say the are not maneuverable in a stoop but as you would surmise their maneuverability is greatly reduced at speed. Another very interesting feature of the bird is its nostrils. Small bony tubercles in a falcon's nostrils guide the air and shock wave to prevent over pressuring the lungs and giving the bird the ability to breath while diving.
so while looking to nature can be inspiring for aeronautical design there are very real limitations in duplicating the ability of a bird with mechanical devices. Another instance would be the original Wright Flyer. It did not have ailerons, it used what is called "Wing warping" which is what birds do, but it was found to be quite impractical since the amount of wing warping required to provide the same effectiveness as a bird required that the wings be so flexible to the point of losing to much strength. Now birds do Wing warping one better as they can not only warp their wings but they can dip a wing, decrease span, warp, move their tail in all axes, and do this all at the same time, providing maneuverability that airplane designers can only dream of.
On whales and submarines. If it were not for the requirement that we a) Keep the water out of the people tank and b) be able to stay submerged for months on end, and c) carry weapons that are stand-off capable, perhaps a Blue Whale would be a decent model to study in submarine development, but not as much as one would think. One must remember that a whale of any kind is a completely articulated bit of construction. It can bend and twist in any direction thus altering its hydrodynamic profile at will. Careful study of its means of propulsion reveals that it is a "whole body" movement, not simply a movement of the flukes in an up and down motion. It was also discovered some time ago that whales overcome friction in the water by way of their blubber. Careful examination revealed that hydrodynamic pressure is relieved by the blubber and skin actualy undulating in concert with the pressure waves to facilitate their movement dow
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Interesting but limited... (Score:2)
However, unless we're talking unmanned vehicles, I'd think a serious limitation in any design is the not-designed-for-flight blob of human goo sitting in the cockpit. You can strap pressure pants on to stop them from blacking out in higher G's than normal, but in general, our physiology is not tailored to the stresses of flight that birds can achieve daily. We're a ground-based ent
mother nature, patents (Score:2, Funny)
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Strange title (Score:5, Funny)
Birds Give a Lesson to Plane Designers
By crapping on their freshly washed cars?
no shit sherlock (Score:2)
N.
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http://www.time.com/time/magazine/article/0,9171,840655-2,00.html [time.com]
Shaken by the near tragedy, but determined to put its lessons to good use on the remaining four Gemini flights, NASA officials last week continued to sift telemetry data to pinpoint the location and determine the cause of Gemini 8's short circuit. They indicated that they will probably include n
Re:PILOTS are limited to 8-10 G's not the planes. (Score:5, Insightful)
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Round my way, they call them a babymother - if you're lucky, you get one as a wife.
What's with the sudden outbreak of 'nigger' trolls, anyway?
Was about 2001 when the last one happened - have the trolls got a 7 year itch, or what?
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Bad economic situation. Unable to criticize current economic system since it's taken as god-given. Scapegoat needed to blow off steam.