The turtle and the robot: an old sea turtle teaches a young engineer a thing or two about swimming.
Stephen Licht built an unusual underwater robot with a curious name. With a wink toward James Joyce, he named it Finnegan, because he was particularly interested in studying the wake made by the robot as it moved through water.
Instead of the usual screw propellers you find on boats or underwater vehicles, Finnegan has four flippers, known to engineers as flapping foils, that roll and twist through the water. They enable Finnegan to change directions quickly and make sharp turns and backflips to avoid obstacles in chaotic, unpredictable environments, such as the waters near reefs or beaches. Licht's vehicle looks--and is designed to move--more like a sea turtle than anything else. But teaching a machine to swim as deftly as a sea turtle is no easy task.
So to make his 500-pound robot more efficient and maneuverable, Licht decided to consult a venerable expert in the field. Her name is Myrtle. She is about the same size and weight as Finnegan, but has much more experience with underwater swimming. She has been doing it for about 70 years, the past 40 in the Giant Ocean Tank at the New England Aquarium.
Licht said, "I called Sherrie Floyd, the chief aquarist at the New England Aquarium, and said, 'I want to do some research with one of your endangered green sea turtles,' and her first question was, 'Well, are you a certified diver?' And I thought, 'OK, I'm in! This is going to be fun.'"
Turtles, fish, penguins, dolphins, and seals are masters at maneuvering in their liquid world, so that's where Licht, a graduate student in the MIT/WHOI Joint Program, turned to learn how to make the next generation of autonomous underwater vehicles, or AUVs, more maneuverable.
"When we look around and see the astounding capabilities of animals in nature," he said, "we see that they have really incredible abilities that we can't even approach with man-made underwater vehicles."
Licht worked with his mentors, MIT professors Michael Triantafyllou and Franz Hover, in a field known as biomimetic robotics. Their goal was to observe nature's solution to a problem, distill it to the basic underlying physics, and apply this new understanding to an engineering problem.
"In this case, what we're really looking at is dynamic, unpredictable flows--like the surf zone, like around obstacles, or in waves," he said. In such conditions, a vehicle has to respond almost instantaneously to substantial forces from the water around it. You've heard the old expression that a battleship can't turn on a dime. Neither can a conventional torpedo-shaped AUV; its single-screw propulsion is designed to move the vehicle efficiently from point A to point B.
This is great for surveys in which the vehicle goes back and forth in long rows, like mowing a lawn. But limited maneuverability means that operators have to avoid dynamic environments or risk crashing and losing a vehicle.
"If you look at the way animals use their bodies, they are extremely comfortable--in fact, usually more comfortable--being near obstacles and dynamic flows," Licht said. Small fish dart into coral reef holes to escape predators. Salmon and trout synchronize their bodies to the flow behind rocks to conserve energy as they swim upriver to spawn. Dolphins surf on the bow waves of huge supertankers that could easily crush them. Licht said he was trying to "learn what lessons we can from animals."
One of these lessons is unsteady propulsion. The marine animals mentioned earlier have many differences, but they use their fins, flippers, and flukes in the same way to move through water. The principles underlying this kind of propulsion are different from those for a conventional screw propeller. To better understand how these animals swim, Licht designed Finnegan with four flapping foils.
An elegant wake
If the key to biomimetics is finding the underlying physics, the key to flapping foil propulsion is understanding the fluid dynamics driving Finnegan's wake. As the foils sweep through the water, they generate tiny tornadoes of spinning water called vortices (picture the eddies formed when you paddle a canoe).
Intricate patterns of vortices spin out into the wake behind the foils. The vortex patterns depend on exactly how the foils move. Some foil strokes produce a trail of vortices with the top set spinning clockwise and the bottom set rotating counterclockwise. Together, they work like cogs in a machine, creating a backward-flowing jet of water that pushes Finnegan forward (see illustration on Page 25). Other foil strokes make Finnegan pull water along with it, creating a drag wake that slows Finnegan down. Some foil strokes create asymmetric vortex patterns that produce lift--these push Finnegan up, down, or to either side. Some vortex patterns are efficient; others waste a lot of energy.
"You can come up with some very basic characteristics of the wakes that make it relatively easy to predict whether you're going to get efficient motion, efficient swimming, efficient thrust, and effective maneuvering capabilities out of them," Licht said. Armed with basic understanding of Finnegan's wake hydrodyamics, Licht took his robot to the MIT Alumni Pool for testing.
"It's always fun to see what you created actually do what you created it to do," he said. "At first, you just want to make sure that it can swim in a straight line, and that it's not going to leak, and it's not going to explode. The next time you go in, you want to make sure it can turn in circles. And by the end of it, two or three years later, you're doing maneuvers. Each time you go in there something might go wrong, but something great might happen."
Swimming with turtles
With Finnegan functioning at a basic level, Licht began to explore the complexities of more difficult maneuvers with Myrtle, whose body had been tuned by nature through millions of years of evolution. Donning scuba gear, he dove in the aquarium's four-story, 200,000-gallon Giant Ocean Tank. He filmed Myrtle's flipper movements from different angles as she maneuvered around the tank. Sometimes he worked with another diver to get her to move in a certain way.
When she was hungry, Myrtle was a very cooperative subject. "Basically if you give her enough lettuce, she'll go in whatever direction you want," Licht said.
But there were other times that she just did whatever she wanted. Licht remembers that once he had to bodycheck Myrtle to keep her from running into the camera and flooding the housing.
Myrtle was a great example of a natural swimmer. Analyzing her flipper movements provided Licht with further insight on how to coordinate the motions of all four foils to drive Finnegan through a maneuver.
Observing Myrtle also prompted Licht to make a slight modification to Finnegan's mechanical shoulders, allowing them to roll over a greater arc and improving Finnegan's ability to make level turns.
"Watching her do them, it was very clear what we were doing wrong," Licht said. The shoulder modification also let Finnegan pitch up and invert itself in just two flipper strokes.
With Myrtle's help, Licht made Finnegan into a highly maneuverable AUV that could perform aggressive maneuvers to avoid obstacles and turn without losing speed.
"We'd run Finnegan up to a meter and a half per second (3 knots, full speed) and aim it at the wall and basically two body lengths away, we would turn it on its side and do a banked turn." You have to be pretty confident about your vehicle to do a maneuver like that.
Licht admits that Finnegan is not ready for the open ocean. The way it is built today, corrosion would be a big problem in salt water. And, even though Finnegan is designed to be autonomous and swim freely on preprogrammed missions, Licht always used a tether, so that if there were ever a flaw in a mission plan or some other kind of technical error, Finnegan could be pulled back in. A lot needs to be done before engineers can put Finnegan in deep water, let it get out of sight, and expect it to come back.
Learn from, don't mimic
Licht likes to remind people that biomimetics isn't about copying nature directly.
"If you look at turtles, for instance, you'll notice that they have much more strength sweeping their flippers under their bodies than pulling them up," he said. "At first, you might think, 'Maybe there's some fundamental swimming property here--that in order to swim like a turtle, you must be stronger on the downstroke than the upstroke.'
"But you just have to understand that turtles have very different survival requirements than underwater vehicles. And one of the reasons that they need this strong downstroke is that they need to be able to pull themselves up the beach in order to breed. Robots don't need to breed; we build them from scratch."
Licht graduated in June 2008 with his Ph.D. degree in oceanographic and mechanical engineering. He now works with Vecna Robotics in Cambridge, Mass., designing robots to rescue wounded soldiers and to work in hospital environments. He also teaches part time at MIT for an undergraduate class on Design of Electromechanical Robotic Systems. Myrtle is still swimming circles around the Giant Ocean Tank at the New England Aquarium. Finnegan is hanging around in the MIT Tow Tank and has been dry for several months--waiting for someone (and some funding) to use it to further advance AUV technology and give Finnegan another chance to amaze us with its underwater acrobatics.
Undersea vehicles can't turn on a dime
Seals swimming fast at 2.4 meters per second need only one-tenth of their body length to turn completely around, in the face of an oncoming coral reef, for example. Like seals, the robot Finnegan has "flippers" (flapping foils). It can't turn as fast or deftly as a seal, but it is more maneuverable than vehicles such as REMUS, which use conventional screw propellers for propulsion.
Sea lion (length: 2.4 meters) Turning radius: 0.1 body lengths traveling at 1 body length per second (2.4 meters per second)
Finnegan (length: 2.0 meters) Turning radius: 0.77 body lengths traveling at 0.72 body lengths per second (1.44 meters per second)
REMUS (length: 1.6 meters) Turning radius: 2.9 body lengths traveling at 0.5 body lengths per second (0.8 meters per second)
The tiny tornadoes of water in Finnegan's wake
How Finnegan's flippers move
As Finnegan's flapping foils sweep through the water, they generate tiny eddies of spinning water called vortices. Different foil strokes produce different trails of vortices.
The thrust strokes create top vortices that spin counterclockwise and bottom vortices that spin clockwise. Together, the vortices work like cogs in a machine, pushing water back and propelling Finnegan forward.
This pattern is the reverse of the thrust pattern. Top vortices spin clockwise and bottom ones spin counterclockwise to create a wake that drags extra water along behind Finnegan and slows it down.
This is like the thrust wake, but deflected downward. The top vortices are stronger than the bottom vortices, pushing water backward and downward, lifting Finnegan up and pushing it forward.
Stephen Licht's research was funded by MIT Sea Grant, a Link Foundation Fellowship, and a National Defense Science and Engineering Graduate Fellowship. Jordan Stanway also received an NDSEG Fellowship and support from the Henry A. Jr. and Elisabeth W. Morss Education Fund.
Jordan Stanway grew up in the mountains J and deserts of Colorado and Utah, but the call of the sea drew him to MIT as an undergraduate to study ocean engineering. Now in the MIT/WHOI Joint Program, be works on AUVs in the Deep Submergence Lab at WHOI. He says he is fascinated with movement through water and hydrodynamics. In his dreams, groups of robot penguins cooperatively explore the ocean depths and leap out of the water to waddle back to the lab. When he's not playing with underwater vehicles, Stanway likes to ride his fixed-gear bike around the Cape and enjoys any chance begets to explore the ocean in person by scuba or free diving.
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|Date:||Dec 1, 2008|
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