RoboCop? How About RoboPenguin! When physicist Flavio Noca first saw penguins zooming around underwater, he was blown away by their speed and maneuverability. Now, his team has built a robotic arm that perfectly mimics the flippers in action — and he says the device could someday propel underwater craft.

RoboCop? How About RoboPenguin!

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This is MORNING EDITION, from NPR News. Happy New Year. I'm Renee Montagne.

At physics conferences these days, a lot of talk is about feathers and fins.

AMY LANG: So, I have studied sharks and also butterflies.

JUSTIN JAWORSKI: Brine shrimps.

HAMID MARVI: Sidewinder rattlesnakes.

SCOTT THOMSON: They're called fire ants.

JANA NAVROTTE: The Hawaiian bobtail squid.

MONTAGNE: More and more physicists are turning to the Animal Kingdom for potential solutions to engineering problems. One particularly odd project caught the attention of NPR's Adam Cole. He brings us the story of a propulsion system inspired by the penguin.


ADAM COLE, BYLINE: Penguins have a comical reputation. They dance for Mary Poppins and play dumb commandos in DreamWorks' "Madagascar."


COLE: And a visit to real, live African penguins at the Maryland Zoo doesn't do much to shake the stereotype. The penguins waddle around in pairs on their rocky island and bray like donkeys.


COLE: One curious penguin stops to peck at the shoelaces of a zookeeper.

JEN KOTTYAN: Her name is Peanut.

COLE: That's avian manager Jen Kottyan. She knows all the penguins by name. There's Peanut, Winnie, Tux and dozens more.

KOTTYAN: They are very, very awkward, and kind of clumsy out on land.

COLE: But when Peanut dives into the water...


COLE: ...she becomes sleek and graceful. And those little wings that seemed so silly on land suddenly become extremely useful.

KOTTYAN: Their wings are small, in proportion to their body. But they are very, very powerful.

COLE: They help Peanut reach 12 miles per hour in the water. She can make sharp turns, move side to side, and accelerate suddenly. It's this maneuverability - hard to achieve in human craft - that so impressed physicist Flavio Noca.

FLAVIO NOCA: I was just amazed by their performance. And that's when, basically, I decided, OK, I want to work on penguins.

COLE: Noca is works at Switzerland's University of Applied Sciences. He says that very little is known about how these champion swimmers manage their underwater acrobatics.

NOCA: There are just, for some reason, only two basic papers.

COLE: So, Noca set out to learn more. He started by filming zoo penguins to track the exact movement of their wings.

NOCA: It was very hard, because penguins have their own mind, so they're not going to go where you want them to go.

COLE: But after watching lots of underwater videos, Noca was able to figure out the exact angle and position of the penguin wing as it completes a stroke. But he still needed a way to model and control that movement in the lab, to understand how it generates its power. So, this year, one of his research assistants built an entirely novel joint mechanism that can perfectly mimic a penguin's flipper stroke.


COLE: With the mechanical flipper churning in the water, Noca can better measure the flows and forces involved. He says someday, this mechanism could help underwater craft dart through ocean.

When Noca presented his work at the American Physical Society's conference in Pittsburgh this winter, he wasn't the only one there talking about animals. Physicists and engineers from all over the world are using new tools - like computer modeling and 3D printing - to study and replicate natural systems. And when I asked them why they're so focused on nature, well, I'll let them explain.

LANG: Nature's been swimming or flying for millions of years.

JAWORSKI: Millions of years of engineering.

NAVROTTE: Millions of years of selection.

LANG: Nature may have solved problems that we're also trying to solve.

THOMSON: So we look to them for inspiration where we're a bit stuck.

MARVI: And it turns out, if you go to the nature and look for the right organism, you are going to find a pretty good solution for that engineering problem.

THOMSON: But it's not necessarily optimal.

NAVROTTE: It doesn't mean it's the only solution. It doesn't mean it's the best solution, but it gives you a direction.

COLE: That was Amy Lang, Jana Navrotte(ph), Justin Jaworski, Hamid Marvi and Scott Thomson.

And I'm Adam Cole, NPR News.

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