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  • so here's three of only three of the

  • Platonic solids, the things you can make

  • out of equilateral triangles. So here

  • I've got tetrahedron, four triangles, octahedron, eight triangles, and

  • the icosahedron, 20 triangles, what's changing

  • as you go from here to here to here is

  • how many triangles there are around each

  • corner or on each vertex so the tetrahedron

  • right has three triangles around the

  • corner and the octahedron has four and the

  • icosahedron has five, what comes next

  • well, six triangles around a vertex do

  • you get a platonic solid that has six

  • triangles around a vertex? no no no what

  • do you get?

  • alright so here's six, here's you know

  • there's one triangle, two, three, four, five,

  • six, so six triangles around vertex that

  • tiles the plane right it goes on forever

  • so it doesn't have any curve to it

  • so here's a way to think about it so

  • your triangle has 60 degrees at this

  • corner and so like 60 plus 60 plus 60

  • those the three around here that adds up

  • 180 which is well less than 360 so it's

  • sort of curves and makes a cone shape

  • you do this with the octahedron you get

  • 60 60 60 60 which is what 240? still less

  • than 30 60 with five of them you got 300

  • when you get 6 it adds up to 360 but

  • there's no there's no lack of space

  • there's no there's nothing missing so it

  • doesn't make a comment just makes it

  • flat 3 4 5 6

  • what happens if you put even if you try

  • and put seven triangles on each vertex?

  • actually you know what would be good to

  • try drawing it. I'm not going to be able

  • to make them all the equalateral but

  • let's see how far we can get. so I got to

  • fit seven, so there's going to be one

  • here and then I got to fit three in

  • here, so i got to do this and all right

  • so I fit seven around a vertex so

  • let's keep going so I got to here

  • already so maybe I'll do that that's

  • five six seven. 3 i gotta fit

  • for and here you can go for quite a

  • while actually before you start running

  • into trouble 1234 you can speed this up

  • right?

  • okay, one two three four, i got to fit three

  • in here you see it starts getting

  • difficult

  • there's too many of them

  • they don't really fit very nicely and

  • you start... now I'm in real trouble look

  • at this one two three four I gotta fit

  • three in here

  • 1234 in here so you can sort of see

  • that this is... well try it at home,

  • how far can you get drawing triangles

  • seven triangles on each vertex. What if i

  • don't do it on paper what if i do it with 3d

  • printed stuff then you get this thing so

  • right well you can see there

  • 1234567 triangles on each vertex you

  • know the first thing you try and do you

  • try and lay it flat and it doesn't work.

  • You can make bits of it be kind of

  • flat and there's some given the hinges

  • which sort of helps out but then it

  • bunches up somewhere else. There's

  • just no way to make it flat everywhere

  • it doesn't work. right what's going on

  • right? these are sort of like they're

  • closed around this or like spheres right?

  • three four and five six is the flat

  • plane. sphere, plane

  • what is this thing trying to be it

  • doesn't look like it's some nice surface

  • is just some horrible thing we don't

  • want seven years maybe it will be better

  • no it is not better right so this is a

  • eight equilateral triangles around each

  • vertex. I mean you can count them

  • to like it is horribly crinkly a sort of

  • like it's like call was like lettuce. so

  • these are positively curved things which

  • like a hill or Bowl sort of curves

  • towards you in all directions, whereas

  • like something that's flat it's not it's coming at all or it can

  • curve in one direction but then the

  • other direction is is flat right doesn't

  • does that make sense?

  • like its curved this way but it has to

  • be flat this where you can curve in both

  • directions so one of the directions

  • plants really just flat and these are

  • like it wants to be like a saddle. if you

  • imagine my hand is a horse right and

  • like the hand is like awesome like your

  • legs go either side of here so so right

  • so what does that mean like sometimes

  • it's coming towards you, and sometimes

  • it's curving away from you, so when

  • you've got both of those that's negative

  • coach or negative gassing curvature so

  • what are these things these are sort of

  • like so these are models of hyperbolic

  • space in a way they're sort of too much

  • of it. it doesn't want to fit in

  • ordinary euclidean space and kind of

  • wrinkles up and gets out of control

  • so these these ones here right you you

  • run out of triangles, right. once you're

  • done with your 20 triangles on the icons

  • evening you're done this one I could

  • have kept going forever right is it's

  • like I could just keep trying this out

  • words and it was just you know for the

  • table and go off around the world this

  • one

  • well so again i've only done like a

  • little bit of its it seems clear that I

  • could keep going

  • I mean I tried doing it over here with

  • the pen but it was sort of you know it's

  • difficult but it seems like you know if

  • you allowed to sort of wrinkle them up

  • out of the plane and like make this sort

  • of wrinkly thing that I could just keep

  • going well you kind of might run into

  • trouble there's actually an open

  • question nobody knows the answer if you

  • keep adding these things

  • how far can you go out into space

  • without it crashing into itself

  • I mean for this physical thing there's a

  • definite limit and and here's here's the

  • argument right so as you sort of go out

  • from like the central ring to the next

  • ring to the next ring like the amount

  • of space you've got to play with his

  • only going up like that the cube of that

  • distance because you're making it a

  • sphere of possible places you could put

  • triangles but the number of triangles

  • that you need actually goes up

  • exponentially so exponential vs cube you

  • lose right you if you go like a few

  • layers out you'll just get incredible

  • numbers of triangles in a solid wall

  • because these are made of plastic the

  • house thickness each one of the house

  • volume and then you just run out but the problem that's open is

  • like suppose there two-dimensional

  • triangles, like connected at the hinges

  • perfectly,

  • how far can you go? is there

  • actually limit? because like two

  • dimensional triangles you could stack

  • like tons of the next to each other and

  • maybe you'd somehow be able to fit them

  • in without crashing into each other we

  • don't think so but there's no proof like

  • nobody knows what's the worst that the

  • father so you can go

  • I mean it's sort of like really quickly

  • and nasty and not really smooth and in

  • the same in same sort of way like the

  • icosahedron is not that smooth it's got

  • these sort of corners so what you can do

  • to an icosahedron to make it smoother is

  • like make a geodesic dome so here's one

  • way to do it right you take each

  • triangle and you subdivide it into for

  • you know like a triforce cut it into

  • four you got these extra vertices on in

  • the middle of the edges and you

  • come out of the sphere and that makes a

  • smoother polyhedron it's no longer

  • regular but you know it's a smooth the

  • thing that's more like it so I was like

  • all right let's do that with this this

  • it's got this crinkly thing that's to like

  • here like the angles add up to

  • 360 plus 60 is 420 too many

  • there's like a lot of angle at each

  • vertex, so if you do this sort of like

  • geodesic dome thing with this thing then

  • it turns into this thing, so this is like

  • it's all hard to see but so

  • I'm going to see this right so these

  • four triangles the the three on the

  • outside or slightly isosceles and the

  • one in the middle is actually equal at

  • all

  • so this is subdivided and then and then

  • the vertices to the activities just

  • squished around a little bit to make it

  • make it a bit smoother and then it's

  • it's nice to write it sort of you can

  • get quite large bits of it to be flat although

  • you can get all of it to be flat always

  • sort of bunches up somewhere

  • no matter how hard you try.

  • yeah it's a hyperbolic doily that's what

  • is really likes to be in sort of like

  • saddles or crinkly start for ya fun to

  • play with the short side so long sides n

  • the short side is n minus 1 so each

  • rectangle is n times n minus 1 this

  • three of them so it's three lots of that

  • and then there's one in the middle

  • well right so that's a really hard

  • question

  • okay all right here we go

so here's three of only three of the

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A2 初級

三角形が多すぎる - Numberphile (Too Many Triangles - Numberphile)

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    林宜悉 に公開 2021 年 01 月 14 日
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