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Today I'd like to show you
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the future of the way we make things.
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I believe that soon our buildings and machines
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will be self-assembling,
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replicating and repairing themselves.
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So I'm going to show you
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what I believe is the current state of manufacturing,
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and then compare that to some natural systems.
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So in the current state of manufacturing, we have skyscrapers --
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two and a half years [of assembly time],
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500,000 to a million parts,
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fairly complex,
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new, exciting technologies in steel, concrete, glass.
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We have exciting machines
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that can take us into space --
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five years [of assembly time], 2.5 million parts.
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But on the other side, if you look at the natural systems,
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we have proteins
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that have two million types,
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can fold in 10,000 nanoseconds,
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or DNA with three billion base pairs
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we can replicate in roughly an hour.
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So there's all of this complexity
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in our natural systems,
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but they're extremely efficient,
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far more efficient than anything we can build,
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far more complex than anything we can build.
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They're far more efficient in terms of energy.
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They hardly ever make mistakes.
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And they can repair themselves for longevity.
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So there's something super interesting about natural systems.
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And if we can translate that
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into our built environment,
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then there's some exciting potential for the way that we build things.
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And I think the key to that is self-assembly.
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So if we want to utilize self-assembly in our physical environment,
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I think there's four key factors.
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The first is that we need to decode
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all of the complexity of what we want to build --
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so our buildings and machines.
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And we need to decode that into simple sequences --
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basically the DNA of how our buildings work.
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Then we need programmable parts
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that can take that sequence
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and use that to fold up, or reconfigure.
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We need some energy that's going to allow that to activate,
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allow our parts to be able to fold up from the program.
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And we need some type of error correction redundancy
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to guarantee that we have successfully built what we want.
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So I'm going to show you a number of projects
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that my colleagues and I at MIT are working on
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to achieve this self-assembling future.
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The first two are the MacroBot and DeciBot.
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So these projects are large-scale reconfigurable robots --
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8 ft., 12 ft. long proteins.
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They're embedded with mechanical electrical devices, sensors.
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You decode what you want to fold up into,
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into a sequence of angles --
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so negative 120, negative 120, 0, 0,
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120, negative 120 -- something like that;
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so a sequence of angles, or turns,
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and you send that sequence through the string.
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Each unit takes its message -- so negative 120 --
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it rotates to that, checks if it got there
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and then passes it to its neighbor.
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So these are the brilliant scientists,
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engineers, designers that worked on this project.
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And I think it really brings to light:
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Is this really scalable?
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I mean, thousands of dollars, lots of man hours
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made to make this eight-foot robot.
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Can we really scale this up? Can we really embed robotics into every part?
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The next one questions that
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and looks at passive nature,
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or passively trying to have reconfiguration programmability.
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But it goes a step further,
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and it tries to have actual computation.
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It basically embeds the most fundamental building block of computing,
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the digital logic gate,
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directly into your parts.
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So this is a NAND gate.
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You have one tetrahedron which is the gate
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that's going to do your computing,
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and you have two input tetrahedrons.
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One of them is the input from the user, as you're building your bricks.
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The other one is from the previous brick that was placed.
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And then it gives you an output in 3D space.
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So what this means
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is that the user can start plugging in what they want the bricks to do.
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It computes on what it was doing before
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and what you said you wanted it to do.
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And now it starts moving in three-dimensional space --
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so up or down.
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So on the left-hand side, [1,1] input equals 0 output, which goes down.
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On the right-hand side,
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[0,0] input is a 1 output, which goes up.
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And so what that really means
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is that our structures now contain the blueprints
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of what we want to build.
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So they have all of the information embedded in them of what was constructed.
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So that means that we can have some form of self-replication.
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In this case I call it self-guided replication,
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because your structure contains the exact blueprints.
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If you have errors, you can replace a part.
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All the local information is embedded to tell you how to fix it.
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So you could have something that climbs along and reads it
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and can output at one to one.
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It's directly embedded; there's no external instructions.
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So the last project I'll show is called Biased Chains,
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and it's probably the most exciting example that we have right now
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of passive self-assembly systems.
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So it takes the reconfigurability
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and programmability
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and makes it a completely passive system.
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So basically you have a chain of elements.
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Each element is completely identical,
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and they're biased.
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So each chain, or each element, wants to turn right or left.
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So as you assemble the chain, you're basically programming it.
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You're telling each unit if it should turn right or left.
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So when you shake the chain,
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it then folds up
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into any configuration that you've programmed in --
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so in this case, a spiral,
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or in this case,
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two cubes next to each other.
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So you can basically program
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any three-dimensional shape --
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or one-dimensional, two-dimensional -- up into this chain completely passively.
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So what does this tell us about the future?
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I think that it's telling us
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that there's new possibilities for self-assembly, replication, repair
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in our physical structures, our buildings, machines.
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There's new programmability in these parts.
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And from that you have new possibilities for computing.
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We'll have spatial computing.
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Imagine if our buildings, our bridges, machines,
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all of our bricks could actually compute.
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That's amazing parallel and distributed computing power,
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new design possibilities.
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So it's exciting potential for this.
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So I think these projects I've showed here
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are just a tiny step towards this future,
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if we implement these new technologies
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for a new self-assembling world.
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Thank you.
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05:57
(Applause)
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