Please double-click on the English subtitles below to play the video.
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I want you to imagine that you're a student in my lab.
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What I want you to do is to create a biologically inspired design.
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And so here's the challenge:
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I want you to help me create a fully 3D, dynamic, parameterized contact model.
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The translation of that is, could you help me build a foot?
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And it is a true challenge, and I do want you to help me.
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Of course, in the challenge there is a prize.
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It's not quite the TED Prize, but it is an exclusive t-shirt from our lab.
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So please send me your ideas about how to design a foot.
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Now if we want to design a foot, what do we have to do?
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We have to first know what a foot is.
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If we go to the dictionary, it says, "It's the lower extremity of a leg
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that is in direct contact with the ground in standing or walking"
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That's the traditional definition.
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But if you wanted to really do research, what do you have to do?
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You have to go to the literature and look up what's known about feet.
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So you go to the literature. (Laughter)
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Maybe you're familiar with this literature.
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The problem is, there are many, many feet.
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How do you do this?
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You need to survey all feet and extract the principles of how they work.
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And I want you to help me do that in this next clip.
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As you see this clip, look for principles,
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and also think about experiments that you might design
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in order to understand how a foot works.
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See any common themes? Principles?
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What would you do?
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What experiments would you run?
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Wow. (Applause)
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Our research on the biomechanics of animal locomotion
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has allowed us to make a blueprint for a foot.
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It's a design inspired by nature, but it's not a copy of any specific foot you just looked at,
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but it's a synthesis of the secrets of many, many feet.
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Now it turns out that animals can go anywhere.
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They can locomote on substrates that vary as you saw --
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in the probability of contact, the movement of that surface
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and the type of footholds that are present.
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If you want to study how a foot works,
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we're going to have to simulate those surfaces, or simulate that debris.
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When we did that, here's a new experiment that we did:
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we put an animal and had it run -- this grass spider --
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on a surface with 99 percent of the contact area removed.
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But it didn't even slow down the animal.
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It's still running at the human equivalent of 300 miles per hour.
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Now how could it do that? Well, look more carefully.
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When we slow it down 50 times we see how the leg is hitting that simulated debris.
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The leg is acting as a foot.
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And in fact, the animal contacts other parts of its leg
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more frequently than the traditionally defined foot.
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The foot is distributed along the whole leg.
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You can do another experiment where you can take a cockroach with a foot,
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and you can remove its foot.
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I'm passing some cockroaches around. Take a look at their feet.
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Without a foot, here's what it does. It doesn't even slow down.
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It can run the same speed without even that segment.
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No problem for the cockroach -- they can grow them back, if you care.
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How do they do it?
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Look carefully: this is slowed down 100 times,
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and watch what it's doing with the rest of its leg.
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It's acting, again, as a distributed foot --
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very effective.
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Now, the question we had is, how general is a distributed foot?
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And the next behavior I'll show you of this animal just stunned us the first time that we saw it.
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Journalists, this is off the record; it's embargoed.
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Take a look at what that is!
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That's a bipedal octopus that's disguised as a rolling coconut.
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It was discovered by Christina Huffard
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and filmed by Sea Studios, right here from Monterey.
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We've also described another species of bipedal octopus.
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This one disguises itself as floating algae.
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It walks on two legs and it holds the other arms up in the air so that it can't be seen.
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(Applause)
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And look what it does with its foot to get over challenging terrain.
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It uses that beautiful distributed foot to make it as if those obstacles are not even there --
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truly extraordinary.
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In 1951, Escher made this drawing. He thought he created an animal fantasy.
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But we know that art imitates life,
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and it turns out nature, three million years ago, evolved the next animal.
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It's a shrimp-like animal called the stomatopod,
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and here's how it moves on the beaches of Panama:
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it actually rolls, and it can even roll uphill.
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It's the ultimate distributed foot: its whole body in this case is acting like its foot.
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So, if we want to then, to our blueprint, add the first important feature,
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we want to add distributed foot contact.
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Not just with the traditional foot, but also the leg,
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and even of the body.
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Can this help us inspire the design of novel robots?
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We biologically inspired this robot, named RHex,
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built by these extraordinary engineers over the last few years.
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RHex's foot started off to be quite simple,
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then it got tuned over time, and ultimately resulted in this half circle.
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Why is that? The video will show you.
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Watch where the robot, now, contacts its leg in order to deal with this very difficult terrain.
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What you'll see, in fact, is that it's using that half circle leg as a distributed foot.
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Watch it go over this.
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You can see it here well on this debris.
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Extraordinary. No sensing, all the control is built right into the tuned legs.
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Really simple, but beautiful.
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Now, you might have noticed something else about the animals
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when they were running over the rough terrain.
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And my assistant's going to help me here.
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When you touched the cockroach leg -- can you get the microphone for him?
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When you touched the cockroach leg, what did it feel like?
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Did you notice something?
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Boy: Spiny.
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Robert Full: It's spiny, right? It's really spiny, isn't it? It sort of hurts.
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Maybe we could give it to our curator and see if he'd be brave enough to touch the cockroach.
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(Laughter)
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Chris Anderson: Did you touch it?
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RF: So if you look carefully at this, what you see is that they have spines
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and until a few weeks ago, no one knew what they did.
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They assumed that they were for protection and for sensory structures.
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We found that they're for something else -- here's a segment of that spine.
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They're tuned such that they easily collapse in one direction
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to pull the leg out from debris,
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but they're stiff in the other direction so they capture disparities in the surface.
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Now crabs don't miss footholds, because they normally move on sand --
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until they come to our lab.
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And where they have a problem with this kind of mesh,
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because they don't have spines.
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The crabs are missing spines, so they have a problem in this kind of rough terrain.
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But of course, we can deal with that
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because we can produce artificial spines.
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We can make spines that catch on simulated debris
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and collapse on removal to easily pull them out.
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We did that by putting these artificial spines on crabs,
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as you see here, and then we tested them.
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Do we really understand that principle of tuning? The answer is, yes!
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This is slowed down 20-fold, and the crab just zooms across that simulated debris.
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(Laughter) (Applause)
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A little better than nature.
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So to our blueprint, we need to add tuned spines.
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Now will this help us think about the design of more effective climbing robots?
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Well, here's RHex: RHex has trouble on rails -- on smooth rails, as you see here.
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So why not add a spine? My colleagues did this at U. Penn.
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Dan Koditschek put some steel nails -- very simple version -- on the robot,
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and here's RHex, now, going over those steel -- those rails. No problem!
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How does it do it?
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Let's slow it down and you can see the spines in action.
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Watch the leg come around, and you'll see it grab on right there.
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It couldn't do that before; it would just slip and get stuck and tip over.
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And watch again, right there -- successful.
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Now just because we have a distributed foot and spines
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doesn't mean you can climb vertical surfaces.
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This is really, really difficult.
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But look at this animal do it!
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One of the ones I'm passing around is climbing up this vertical surface that's a smooth metal plate.
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It's extraordinary how fast it can do it --
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but if you slow it down, you see something that's quite extraordinary.
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It's a secret. The animal effectively climbs by slipping and look --
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and doing, actually, terribly, with respect to grabbing on the surface.
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It looks, in fact, like it's swimming up the surface.
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We can actually model that behavior better as a fluid, if you look at it.
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The distributed foot, actually, is working more like a paddle.
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The same is true when we looked at this lizard running on fluidized sand.
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Watch its feet.
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It's actually functioning as a paddle
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even though it's interacting with a surface that we normally think of as a solid.
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This is not different from what my former undergraduate discovered
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when she figured out how lizards can run on water itself.
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Can you use this to make a better robot?
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Martin Buehler did -- who's now at Boston Dynamics --
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he took this idea and made RHex to be Aqua RHex.
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So here's RHex with paddles,
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now converted into an incredibly maneuverable swimming robot.
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For rough surfaces, though, animals add claws.
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And you probably feel them if you grabbed it.
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Did you touch it?
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CA: I did.
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RF: And they do really well at grabbing onto surfaces with these claws.
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Mark Cutkosky at Stanford University, one of my collaborators, is an extraordinary engineer
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who developed this technique called Shape Deposition Manufacturing,
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where he can imbed claws right into an artificial foot.
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And here's the simple version of a foot for a new robot that I'll show you in a bit.
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So to our blueprint, let's attach claws.
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Now if we look at animals, though, to be really maneuverable in all surfaces,
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the animals use hybrid mechanisms
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that include claws, and spines, and hairs, and pads, and glue, and capillary adhesion
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and a whole bunch of other things.
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These are all from different insects.
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There's an ant crawling up a vertical surface.
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Let's look at that ant.
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This is the foot of an ant. You see the hairs and the claws and this thing here.
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This is when its foot's in the air.
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Watch what happens when the foot goes onto your sandwich.
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You see what happens?
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That pad comes out. And that's where the glue is.
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Here from underneath is an ant foot,
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and when the claws don't dig in, that pad automatically comes out without the ant doing anything.
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It just extrudes.
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And this was a hard shot to get -- I think this is the shot of the ant foot on the superstrings.
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So it's pretty tough to do.
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This is what it looks like close up --
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here's the ant foot, and there's the glue.
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And we discovered this glue may be an interesting two-phase mixture.
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It certainly helps it to hold on.
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So to our blueprint, we stick on some sticky pads.
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Now you might think for smooth surfaces we get inspiration here.
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Now we have something better here.
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The gecko's a really great example of nanotechnology in nature.
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These are its feet.
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They're -- almost look alien. And the secret, which they stick on with,
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involves their hairy toes.
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They can run up a surface at a meter per second,
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take 30 steps in that one second -- you can hardly see them.
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If we slow it down, they attach their feet at eight milliseconds,
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and detach them in 16 milliseconds.
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And when you watch how they detach it, it is bizarre.
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They peel away from the surface like you'd peel away a piece of tape.
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Very strange. How do they stick?
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If you look at their feet, they have leaf-like structures called linalae
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with millions of hairs.
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And each hair has the worst case of split ends possible.
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It has a hundred to a thousand split ends,
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and that's the secret, because it allows intimate contact.
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The gecko has a billion of these 200-nanometer-sized split ends.
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And they don't stick by glue, or they don't work like Velcro, or they don't work with suction.
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We discovered they work by intermolecular forces alone.
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So to our blueprint, we split some hairs.
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This has inspired the design of the first self-cleaning dry adhesive --
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the patent issued, we're happy to say.
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And here's the simplest version in nature,
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and here's my collaborator Ron Fearing's attempt
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at an artificial version of this dry adhesive made from polyurethane.
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And here's the first attempt to have it work on some load.
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There's enormous interest in this in a variety of different fields.
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You could think of a thousand possible uses, I'm sure.
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Lots of people have, and we're excited about realizing this as a product.
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We have imagined products; for example, this one:
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we imagined a bio-inspired Band-Aid, where we took the glue off the Band-Aid.
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We took some hairs from a molting gecko;
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put three rolls of them on here, and then made this Band-Aid.
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This is an undergraduate volunteer --
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we have 30,000 undergraduates so we can choose among them --
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that's actually just a red pen mark.
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But it makes an incredible Band-Aid.
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It's aerated, it can be peeled off easily, it doesn't cause any irritation, it works underwater.
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I think this is an extraordinary example of how curiosity-based research --
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we just wondered how they climbed up something --
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can lead to things that you could never imagine.
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It's just an example of why we need to support curiosity-based research.
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Here you are, pulling off the Band-Aid.
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So we've redefined, now, what a foot is.
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The question is, can we use these secrets, then,
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to inspire the design of a better foot, better than one that we see in nature?
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Here's the new project:
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we're trying to create the first climbing search-and-rescue robot -- no suction or magnets --
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that can only move on limited kinds of surfaces.
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I call the new robot RiSE, for "Robot in Scansorial Environment" -- that's a climbing environment --
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and we have an extraordinary team of biologists and engineers creating this robot.
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And here is RiSE.
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It's six-legged and has a tail. Here it is on a fence and a tree.
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And here are RiSE's first steps on an incline.
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You have the audio? You can hear it go up.
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And here it is coming up at you, in its first steps up a wall.
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Now it's only using its simplest feet here, so this is very new.
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But we think we got the dynamics right of the robot.
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Mark Cutkosky, though, is taking it a step further.
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He's the one able to build this shape-deposition manufactured feet and toes.
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The next step is to make compliant toes,
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and try to add spines and claws and set it for dry adhesives.
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So the idea is to first get the toes and a foot right,
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attempt to make that climb, and ultimately put it on the robot.
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And that's exactly what he's done.
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He's built, in fact, a climbing foot-bot inspired by nature.
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And here's Cutkosky's and his amazing students' design.
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So these are tuned toes -- there are six of them,
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and they use the principles that I just talked about collectively for the blueprint.
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So this is not using any suction, any glue,
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and it will ultimately, when it's attached to the robot --
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it's as biologically inspired as the animal --
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hopefully be able to climb any kind of a surface.
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Here you see it, next, going up the side of a building at Stanford.
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It's sped up -- again, it's a foot climbing.
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It's not the whole robot yet, we're working on it --
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now you can see how it's attaching.
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These tuned structures allow the spines, friction pads and ultimately the adhesive hairs
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to grab onto very challenging, difficult surfaces.
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And so they were able to get this thing -- this is now sped up 20 times --
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can you imagine it trying to go up and rescue somebody at that upper floor? OK?
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You can visualize this now; it's not impossible.
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It's a very challenging task. But more to come later.
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To finish: we've gotten design secrets from nature by looking at how feet are built.
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We've learned we should distribute control to smart parts.
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Don't put it all in the brain,
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but put some of the control in tuned feet, legs and even body.
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That nature uses hybrid solutions, not a single solution, to these problems,
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and they're integrated and beautifully robust.
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And third, we believe strongly that we do not want to mimic nature but instead be inspired by biology,
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and use these novel principles with the best engineering solutions that are out there
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to make -- potentially -- something better than nature.
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So there's a clear message:
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whether you care about a fundamental, basic research
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of really interesting, bizarre, wonderful animals,
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or you want to build a search-and-rescue robot
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that can help you in an earthquake, or to save someone in a fire,
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or you care about medicine, we must preserve nature's designs.
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Otherwise these secrets will be lost forever.
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Thank you.
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