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  • So say you're Arthur Stone, and you're

  • showing your hexaflexagon to your friend, Tuckerman,

  • and you've already blown his mind by showing him

  • it has three sides-- orange, yellow, pink, orange, yellow,

  • pink-- but now you're about to extra super blow

  • his mind by showing him that there's even more colors.

  • And he's like, whoa, where did the blue side come from?

  • But you're having trouble finding all six.

  • Like, you know there's a green side somewhere in here,

  • but where is it?

  • You're all like, OK, Tuckerman, I think I found the green side.

  • It's right in here.

  • Anyway, Tuckerman immediately decides

  • he needs to discover the fastest way

  • to get to all the colors, which he calls the Tuckerman

  • traverse.

  • So you and Tuckerman are working on that,

  • and there's hexaflexagons all over the lunch table,

  • and another student is curious about what you're doing

  • and wants to join your committee.

  • His name is Richard Feynman.

  • So stop being Arthur Stone, and start being Brian Tuckerman.

  • So you're Tuckerman, and you teach Feynman

  • how to make the hexa-hexaflexagon

  • by first folding a strip of 18 triangles with the 19th

  • for gluing.

  • You and Stone have just figured out how to number

  • the faces before you fold them by dissecting

  • a perfect specimen.

  • You number them 1-2-3, 1-2-3, 1-2-3, 1-2-3, 1-2-3, 1-2-3.

  • Glue on one side.

  • Flip it, and glue 4, 4, 5, 5, 6, 6, 4, 4, 5, 5, 6, 6, 4, 4, 5,

  • 5, 6, 6 on the other.

  • You coil it around so that you get ones and twos

  • and threes on the outside like 1, 2, 2, 3, 3, 1, 1 2, 2, 3, 3,

  • and then fold that around into a hexagon,

  • so that all the twos are on the front.

  • And then flip it, and glue the two blue parts together,

  • so that all threes are on the back.

  • Feynman has some trouble flexing it,

  • but you show him how to pinch two triangles together and then

  • push in the opposite side.

  • He somehow still does it wrong and ends up doing it backwards,

  • flexing in reverse.

  • Now he's all intrigued by all the flexing possibilities,

  • and you're like, let me show you the Tuckerman traverse.

  • But Feynman, being Feynman, is like, we must create a diagram.

  • And Tuckerman's like, really, it's not that hard.

  • No, diagram.

  • So you're Feynman, and you've already

  • seen you can cycle from one to two to three, one, two, three.

  • So you write that down with arrows and stuff.

  • Or you can go backwards, but from one, two, and three, you

  • can also flex the other way, in which case one goes to six,

  • or two to five, or three to four.

  • And if you did one to six, once you're at six,

  • you can only flex one way, because the other doesn't work.

  • You have to go to three or backwards back to one.

  • But then you notice that if you go to three,

  • you can only flex one way, and the other is un-open-up-able.

  • But before when you were on three,

  • you could go either to one or four,

  • but now you can only go to one.

  • And you can go backwards to six, but not

  • backwards to two, which means that this three isn't

  • the same three as the first three.

  • Somehow it's the same color, but in a different state.

  • You show this to your friend John Tukey,

  • and he's like, oh yeah, that makes sense.

  • And he draws a star in the middle of your three

  • and sits back as if that explained everything.

  • So you're like, whatever, and flip it back around

  • to get to the other three and check it.

  • The star turns into a not star.

  • And from this alternate three, there's

  • this 1-6-3 loop that connects to the main loop at one, which

  • is the same one as one has always been.

  • But there's a different one off of the main two

  • in the 2-5-1 loop.

  • And of course, everything looks different if you flip it over.

  • And these threes are also different,

  • because they have different numbers on the other side.

  • And you complete a diagram of possibilities,

  • which allows you to find the optimal Tuckerman traverse.

  • You also diagram the original trihexaflexagon,

  • which is pretty simple.

  • The flexagon committee approves your diagrams

  • and decides to call them Feynman diagrams.

  • Everything is going great until 1941,

  • because suddenly there's important war stuff to do,

  • and flexagons are largely forgotten.

  • OK.

  • Now fast forward 15 years, and be Martin Gardner.

  • You're an amateur magician, and you're

  • hanging out at your friend's place

  • talking about magician stuff.

  • Anyway your friend shows you something

  • you've never seen before-- a big flexagon he's

  • made out of cloth.

  • And you're thinking, hey, this is awesome.

  • Maybe other people would like to know about this flexagon thing.

  • So you write an article for Scientific American,

  • and soon you've landed yourself a gig writing a regular column

  • about recreational mathematics called "Mathematical Games,"

  • and it's a huge success and gets hundreds of comments.

  • I mean, letters, and there's nothing else like your column.

  • And all the cool people are inspired by you,

  • and you're pretty much the reason

  • why people know about things like tangrams,

  • and Conway's Game of Life, and the work of MC Escher,

  • and other things like that.

  • Now fast forward 50 years, and say you're

  • me in the generation of people inspired by Martin Gardner

  • are now the people inspiring you.

  • So he's your math inspiration grandfather.

  • And now you yourself are in the business of mathematically

  • inspiring people, and you want them

  • to be aware of their math inspiration heritage.

  • OK, now say you are you.

  • If you think hexaflexagons are cool

  • that was just column number one.

  • And I invite you to join in with the hundreds of people

  • to celebrate Martin Gardner's birthday every October 21.

  • This year, there will be hexaflexagon

  • parties in homes and schools all over the world.

  • And if you want to attend or host one,

  • check the description.

  • I'm celebrating by making these videos,

  • and also I just like the image of flexagons everywhere--

  • floating around lunch tables, spilling out of your pockets,

  • lost in your couch cushions.

  • I like to keep some ready to deploy out

  • of my wallet or tiny yellow purse,

  • in case of a flexagon emergency.

  • And then there's more recent innovations

  • in flexagon technology, and all the cool ways to color

  • them, and other stuff.

  • But that will have to wait until next time.

So say you're Arthur Stone, and you're

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B1 中級

六面體2 (Hexaflexagons 2)

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    林宜悉 發佈於 2021 年 01 月 14 日
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