Skylar Tibbits: Can we make things that make themselves?

75,656 views ・ 2011-09-01

TED


Please double-click on the English subtitles below to play the video.

00:15
Today I'd like to show you
0
15260
2000
00:17
the future of the way we make things.
1
17260
2000
00:19
I believe that soon our buildings and machines
2
19260
2000
00:21
will be self-assembling,
3
21260
2000
00:23
replicating and repairing themselves.
4
23260
2000
00:25
So I'm going to show you
5
25260
2000
00:27
what I believe is the current state of manufacturing,
6
27260
2000
00:29
and then compare that to some natural systems.
7
29260
3000
00:32
So in the current state of manufacturing, we have skyscrapers --
8
32260
3000
00:35
two and a half years [of assembly time],
9
35260
2000
00:37
500,000 to a million parts,
10
37260
2000
00:39
fairly complex,
11
39260
2000
00:41
new, exciting technologies in steel, concrete, glass.
12
41260
3000
00:44
We have exciting machines
13
44260
2000
00:46
that can take us into space --
14
46260
2000
00:48
five years [of assembly time], 2.5 million parts.
15
48260
3000
00:51
But on the other side, if you look at the natural systems,
16
51260
3000
00:54
we have proteins
17
54260
2000
00:56
that have two million types,
18
56260
2000
00:58
can fold in 10,000 nanoseconds,
19
58260
2000
01:00
or DNA with three billion base pairs
20
60260
2000
01:02
we can replicate in roughly an hour.
21
62260
3000
01:05
So there's all of this complexity
22
65260
2000
01:07
in our natural systems,
23
67260
2000
01:09
but they're extremely efficient,
24
69260
2000
01:11
far more efficient than anything we can build,
25
71260
2000
01:13
far more complex than anything we can build.
26
73260
2000
01:15
They're far more efficient in terms of energy.
27
75260
2000
01:17
They hardly ever make mistakes.
28
77260
3000
01:20
And they can repair themselves for longevity.
29
80260
2000
01:22
So there's something super interesting about natural systems.
30
82260
3000
01:25
And if we can translate that
31
85260
2000
01:27
into our built environment,
32
87260
2000
01:29
then there's some exciting potential for the way that we build things.
33
89260
2000
01:31
And I think the key to that is self-assembly.
34
91260
3000
01:34
So if we want to utilize self-assembly in our physical environment,
35
94260
3000
01:37
I think there's four key factors.
36
97260
2000
01:39
The first is that we need to decode
37
99260
2000
01:41
all of the complexity of what we want to build --
38
101260
2000
01:43
so our buildings and machines.
39
103260
2000
01:45
And we need to decode that into simple sequences --
40
105260
2000
01:47
basically the DNA of how our buildings work.
41
107260
2000
01:49
Then we need programmable parts
42
109260
2000
01:51
that can take that sequence
43
111260
2000
01:53
and use that to fold up, or reconfigure.
44
113260
3000
01:56
We need some energy that's going to allow that to activate,
45
116260
3000
01:59
allow our parts to be able to fold up from the program.
46
119260
3000
02:02
And we need some type of error correction redundancy
47
122260
2000
02:04
to guarantee that we have successfully built what we want.
48
124260
3000
02:07
So I'm going to show you a number of projects
49
127260
2000
02:09
that my colleagues and I at MIT are working on
50
129260
2000
02:11
to achieve this self-assembling future.
51
131260
2000
02:13
The first two are the MacroBot and DeciBot.
52
133260
3000
02:16
So these projects are large-scale reconfigurable robots --
53
136260
4000
02:20
8 ft., 12 ft. long proteins.
54
140260
3000
02:23
They're embedded with mechanical electrical devices, sensors.
55
143260
3000
02:26
You decode what you want to fold up into,
56
146260
2000
02:28
into a sequence of angles --
57
148260
2000
02:30
so negative 120, negative 120, 0, 0,
58
150260
2000
02:32
120, negative 120 -- something like that;
59
152260
3000
02:35
so a sequence of angles, or turns,
60
155260
2000
02:37
and you send that sequence through the string.
61
157260
3000
02:40
Each unit takes its message -- so negative 120 --
62
160260
3000
02:43
it rotates to that, checks if it got there
63
163260
2000
02:45
and then passes it to its neighbor.
64
165260
3000
02:48
So these are the brilliant scientists,
65
168260
2000
02:50
engineers, designers that worked on this project.
66
170260
2000
02:52
And I think it really brings to light:
67
172260
2000
02:54
Is this really scalable?
68
174260
2000
02:56
I mean, thousands of dollars, lots of man hours
69
176260
2000
02:58
made to make this eight-foot robot.
70
178260
3000
03:01
Can we really scale this up? Can we really embed robotics into every part?
71
181260
3000
03:04
The next one questions that
72
184260
2000
03:06
and looks at passive nature,
73
186260
2000
03:08
or passively trying to have reconfiguration programmability.
74
188260
3000
03:11
But it goes a step further,
75
191260
2000
03:13
and it tries to have actual computation.
76
193260
2000
03:15
It basically embeds the most fundamental building block of computing,
77
195260
2000
03:17
the digital logic gate,
78
197260
2000
03:19
directly into your parts.
79
199260
2000
03:21
So this is a NAND gate.
80
201260
2000
03:23
You have one tetrahedron which is the gate
81
203260
2000
03:25
that's going to do your computing,
82
205260
2000
03:27
and you have two input tetrahedrons.
83
207260
2000
03:29
One of them is the input from the user, as you're building your bricks.
84
209260
3000
03:32
The other one is from the previous brick that was placed.
85
212260
3000
03:35
And then it gives you an output in 3D space.
86
215260
3000
03:38
So what this means
87
218260
2000
03:40
is that the user can start plugging in what they want the bricks to do.
88
220260
3000
03:43
It computes on what it was doing before
89
223260
2000
03:45
and what you said you wanted it to do.
90
225260
2000
03:47
And now it starts moving in three-dimensional space --
91
227260
2000
03:49
so up or down.
92
229260
2000
03:51
So on the left-hand side, [1,1] input equals 0 output, which goes down.
93
231260
3000
03:54
On the right-hand side,
94
234260
2000
03:56
[0,0] input is a 1 output, which goes up.
95
236260
3000
03:59
And so what that really means
96
239260
2000
04:01
is that our structures now contain the blueprints
97
241260
2000
04:03
of what we want to build.
98
243260
2000
04:05
So they have all of the information embedded in them of what was constructed.
99
245260
3000
04:08
So that means that we can have some form of self-replication.
100
248260
3000
04:11
In this case I call it self-guided replication,
101
251260
3000
04:14
because your structure contains the exact blueprints.
102
254260
2000
04:16
If you have errors, you can replace a part.
103
256260
2000
04:18
All the local information is embedded to tell you how to fix it.
104
258260
3000
04:21
So you could have something that climbs along and reads it
105
261260
2000
04:23
and can output at one to one.
106
263260
2000
04:25
It's directly embedded; there's no external instructions.
107
265260
2000
04:27
So the last project I'll show is called Biased Chains,
108
267260
3000
04:30
and it's probably the most exciting example that we have right now
109
270260
3000
04:33
of passive self-assembly systems.
110
273260
2000
04:35
So it takes the reconfigurability
111
275260
2000
04:37
and programmability
112
277260
2000
04:39
and makes it a completely passive system.
113
279260
3000
04:43
So basically you have a chain of elements.
114
283260
2000
04:45
Each element is completely identical,
115
285260
2000
04:47
and they're biased.
116
287260
2000
04:49
So each chain, or each element, wants to turn right or left.
117
289260
3000
04:52
So as you assemble the chain, you're basically programming it.
118
292260
3000
04:55
You're telling each unit if it should turn right or left.
119
295260
3000
04:58
So when you shake the chain,
120
298260
3000
05:01
it then folds up
121
301260
2000
05:03
into any configuration that you've programmed in --
122
303260
3000
05:06
so in this case, a spiral,
123
306260
2000
05:08
or in this case,
124
308260
3000
05:11
two cubes next to each other.
125
311260
3000
05:14
So you can basically program
126
314260
2000
05:16
any three-dimensional shape --
127
316260
2000
05:18
or one-dimensional, two-dimensional -- up into this chain completely passively.
128
318260
3000
05:21
So what does this tell us about the future?
129
321260
2000
05:23
I think that it's telling us
130
323260
2000
05:25
that there's new possibilities for self-assembly, replication, repair
131
325260
3000
05:28
in our physical structures, our buildings, machines.
132
328260
3000
05:31
There's new programmability in these parts.
133
331260
2000
05:33
And from that you have new possibilities for computing.
134
333260
2000
05:35
We'll have spatial computing.
135
335260
2000
05:37
Imagine if our buildings, our bridges, machines,
136
337260
2000
05:39
all of our bricks could actually compute.
137
339260
2000
05:41
That's amazing parallel and distributed computing power,
138
341260
2000
05:43
new design possibilities.
139
343260
2000
05:45
So it's exciting potential for this.
140
345260
2000
05:47
So I think these projects I've showed here
141
347260
2000
05:49
are just a tiny step towards this future,
142
349260
2000
05:51
if we implement these new technologies
143
351260
2000
05:53
for a new self-assembling world.
144
353260
2000
05:55
Thank you.
145
355260
2000
05:57
(Applause)
146
357260
2000
About this website

This site will introduce you to YouTube videos that are useful for learning English. You will see English lessons taught by top-notch teachers from around the world. Double-click on the English subtitles displayed on each video page to play the video from there. The subtitles scroll in sync with the video playback. If you have any comments or requests, please contact us using this contact form.

https://forms.gle/WvT1wiN1qDtmnspy7