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The mathematician who cracked Wall Street

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    Chris Anderson: You were something
    of a mathematical phenom.
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    You had already taught at Harvard
    and MIT at a young age.
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    And then the NSA came calling.
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    What was that about?
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    Jim Simons: Well the NSA --
    that's the National Security Agency --
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    they didn't exactly come calling.
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    They had an operation at Princeton,
    where they hired mathematicians
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    to attack secret codes
    and stuff like that.
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    And I knew that existed.
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    And they had a very good policy,
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    because you could do half your time
    at your own mathematics,
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    and at least half your time
    working on their stuff.
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    And they paid a lot.
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    So that was an irresistible pull.
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    So, I went there.
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    CA: You were a code-cracker.
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    JS: I was.
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    CA: Until you got fired.
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    JS: Well, I did get fired. Yes.
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    CA: How come?
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    JS: Well, how come?
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    I got fired because,
    well, the Vietnam War was on,
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    and the boss of bosses in my organization
    was a big fan of the war
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    and wrote a New York Times article,
    a magazine section cover story,
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    about how we would win in Vietnam.
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    And I didn't like that war,
    I thought it was stupid.
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    And I wrote a letter to the Times,
    which they published,
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    saying not everyone
    who works for Maxwell Taylor,
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    if anyone remembers that name,
    agrees with his views.
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    And I gave my own views ...
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    CA: Oh, OK. I can see that would --
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    JS: ... which were different
    from General Taylor's.
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    But in the end, nobody said anything.
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    But then, I was 29 years old at this time,
    and some kid came around
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    and said he was a stringer
    from Newsweek magazine
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    and he wanted to interview me
    and ask what I was doing about my views.
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    And I told him, "I'm doing
    mostly mathematics now,
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    and when the war is over,
    then I'll do mostly their stuff."
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    Then I did the only
    intelligent thing I'd done that day --
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    I told my local boss
    that I gave that interview.
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    And he said, "What'd you say?"
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    And I told him what I said.
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    And then he said,
    "I've got to call Taylor."
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    He called Taylor; that took 10 minutes.
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    I was fired five minutes after that.
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    CA: OK.
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    JS: But it wasn't bad.
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    CA: It wasn't bad,
    because you went on to Stony Brook
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    and stepped up your mathematical career.
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    You started working with this man here.
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    Who is this?
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    JS: Oh, [Shiing-Shen] Chern.
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    Chern was one of the great
    mathematicians of the century.
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    I had known him when
    I was a graduate student at Berkeley.
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    And I had some ideas,
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    and I brought them to him
    and he liked them.
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    Together, we did this work
    which you can easily see up there.
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    There it is.
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    CA: It led to you publishing
    a famous paper together.
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    Can you explain at all what that work was?
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    JS: No.
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    (Laughter)
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    JS: I mean, I could
    explain it to somebody.
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    (Laughter)
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    CA: How about explaining this?
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    JS: But not many. Not many people.
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    CA: I think you told me
    it had something to do with spheres,
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    so let's start here.
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    JS: Well, it did,
    but I'll say about that work --
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    it did have something to do with that,
    but before we get to that --
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    that work was good mathematics.
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    I was very happy with it; so was Chern.
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    It even started a little sub-field
    that's now flourishing.
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    But, more interestingly,
    it happened to apply to physics,
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    something we knew nothing about --
    at least I knew nothing about physics,
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    and I don't think Chern
    knew a heck of a lot.
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    And about 10 years
    after the paper came out,
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    a guy named Ed Witten in Princeton
    started applying it to string theory
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    and people in Russia started applying it
    to what's called "condensed matter."
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    Today, those things in there
    called Chern-Simons invariants
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    have spread through a lot of physics.
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    And it was amazing.
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    We didn't know any physics.
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    It never occurred to me
    that it would be applied to physics.
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    But that's the thing about mathematics --
    you never know where it's going to go.
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    CA: This is so incredible.
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    So, we've been talking about
    how evolution shapes human minds
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    that may or may not perceive the truth.
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    Somehow, you come up
    with a mathematical theory,
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    not knowing any physics,
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    discover two decades later
    that it's being applied
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    to profoundly describe
    the actual physical world.
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    How can that happen?
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    JS: God knows.
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    (Laughter)
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    But there's a famous physicist
    named [Eugene] Wigner,
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    and he wrote an essay on the unreasonable
    effectiveness of mathematics.
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    Somehow, this mathematics,
    which is rooted in the real world
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    in some sense -- we learn to count,
    measure, everyone would do that --
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    and then it flourishes on its own.
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    But so often it comes
    back to save the day.
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    General relativity is an example.
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    [Hermann] Minkowski had this geometry,
    and Einstein realized,
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    "Hey! It's the very thing
    in which I can cast general relativity."
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    So, you never know. It is a mystery.
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    It is a mystery.
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    CA: So, here's a mathematical
    piece of ingenuity.
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    Tell us about this.
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    JS: Well, that's a ball -- it's a sphere,
    and it has a lattice around it --
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    you know, those squares.
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    What I'm going to show here was
    originally observed by [Leonhard] Euler,
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    the great mathematician, in the 1700's.
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    And it gradually grew to be
    a very important field in mathematics:
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    algebraic topology, geometry.
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    That paper up there had its roots in this.
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    So, here's this thing:
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    it has eight vertices,
    twelve edges, six faces.
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    And if you look at the difference --
    vertices minus edges plus faces --
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    you get two.
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    OK, well, two. That's a good number.
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    Here's a different way of doing it --
    these are triangles covering --
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    this has 12 vertices and 30 edges
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    and 20 faces, 20 tiles.
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    And vertices minus edges
    plus faces still equals two.
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    And in fact, you could do this
    any which way --
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    cover this thing with all kinds
    of polygons and triangles
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    and mix them up.
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    And you take vertices minus edges
    plus faces -- you'll get two.
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    Here's a different shape.
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    This is a torus, or the surface
    of a doughnut: 16 vertices
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    covered by these rectangles,
    32 edges, 16 faces.
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    Vertices minus edges comes out to be zero.
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    It'll always come out to zero.
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    Every time you cover a torus
    with squares or triangles
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    or anything like that,
    you're going to get zero.
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    So, this is called
    the Euler characteristic.
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    And it's what's called
    a topological invariant.
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    It's pretty amazing.
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    No matter how you do it,
    you're always get the same answer.
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    So that was the first sort of thrust,
    from the mid-1700s,
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    into a subject which is now called
    algebraic topology.
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    CA: And your own work
    took an idea like this and moved it
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    into higher-dimensional theory,
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    higher-dimensional objects,
    and found new invariances?
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    JS: Yes. Well, there were already
    higher-dimensional invariants:
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    Pontryagin classes --
    actually, there were Chern classes.
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    There were a bunch
    of these types of invariants.
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    I was struggling to work on one of them
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    and model it sort of combinatorially,
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    instead of the way it was typically done,
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    and that led to this work
    and we uncovered some new things.
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    But if it wasn't for Mr. Euler --
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    who wrote almost 70 volumes of mathematics
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    and had 13 children,
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    who he apparently would dandle on his knee
    while he was writing --
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    if it wasn't for Mr. Euler, there wouldn't
    perhaps be these invariants.
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    CA: OK, so that's at least given us
    a flavor of that amazing mind in there.
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    Let's talk about Renaissance.
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    Because you took that amazing mind
    and having been a code-cracker at the NSA,
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    you started to become a code-cracker
    in the financial industry.
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    I think you probably didn't buy
    efficient market theory.
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    Somehow you found a way of creating
    astonishing returns over two decades.
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    The way it's been explained to me,
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    what's remarkable about what you did
    wasn't just the size of the returns,
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    it's that you took them
    with surprisingly low volatility and risk,
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    compared with other hedge funds.
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    So how on earth did you do this, Jim?
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    JS: I did it by assembling
    a wonderful group of people.
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    When I started doing trading, I had
    gotten a little tired of mathematics.
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    I was in my late 30s,
    I had a little money.
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    I started trading and it went very well.
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    I made quite a lot of money
    with pure luck.
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    I mean, I think it was pure luck.
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    It certainly wasn't mathematical modeling.
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    But in looking at the data,
    after a while I realized:
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    it looks like there's some structure here.
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    And I hired a few mathematicians,
    and we started making some models --
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    just the kind of thing we did back
    at IDA [Institute for Defense Analyses].
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    You design an algorithm,
    you test it out on a computer.
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    Does it work? Doesn't it work? And so on.
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    CA: Can we take a look at this?
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    Because here's a typical graph
    of some commodity.
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    I look at that, and I say,
    "That's just a random, up-and-down walk --
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    maybe a slight upward trend
    over that whole period of time."
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    How on earth could you trade
    looking at that,
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    and see something that wasn't just random?
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    JS: In the old days -- this is
    kind of a graph from the old days,
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    commodities or currencies
    had a tendency to trend.
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    Not necessarily the very light trend
    you see here, but trending in periods.
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    And if you decided, OK,
    I'm going to predict today,
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    by the average move in the past 20 days --
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    maybe that would be a good prediction,
    and I'd make some money.
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    And in fact, years ago,
    such a system would work --
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    not beautifully, but it would work.
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    You'd make money, you'd lose
    money, you'd make money.
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    But this is a year's worth of days,
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    and you'd make a little money
    during that period.
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    It's a very vestigial system.
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    CA: So you would test
    a bunch of lengths of trends in time
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    and see whether, for example,
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    a 10-day trend or a 15-day trend
    was predictive of what happened next.
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    JS: Sure, you would try all those things
    and see what worked best.
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    Trend-following would
    have been great in the '60s,
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    and it was sort of OK in the '70s.
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    By the '80s, it wasn't.
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    CA: Because everyone could see that.
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    So, how did you stay ahead of the pack?
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    JS: We stayed ahead of the pack
    by finding other approaches --
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    shorter-term approaches to some extent.
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    The real thing was to gather
    a tremendous amount of data --
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    and we had to get it by hand
    in the early days.
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    We went down to the Federal Reserve
    and copied interest rate histories
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    and stuff like that,
    because it didn't exist on computers.
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    We got a lot of data.
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    And very smart people -- that was the key.
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    I didn't really know how to hire
    people to do fundamental trading.
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    I had hired a few -- some made money,
    some didn't make money.
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    I couldn't make a business out of that.
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    But I did know how to hire scientists,
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    because I have some taste
    in that department.
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    So, that's what we did.
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    And gradually these models
    got better and better,
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    and better and better.
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    CA: You're credited with doing
    something remarkable at Renaissance,
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    which is building this culture,
    this group of people,
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    who weren't just hired guns
    who could be lured away by money.
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    Their motivation was doing
    exciting mathematics and science.
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    JS: Well, I'd hoped that might be true.
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    But some of it was money.
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    CA: They made a lot of money.
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    JS: I can't say that no one came
    because of the money.
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    I think a lot of them
    came because of the money.
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    But they also came
    because it would be fun.
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    CA: What role did machine learning
    play in all this?
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    JS: In a certain sense,
    what we did was machine learning.
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    You look at a lot of data, and you try
    to simulate different predictive schemes,
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    until you get better and better at it.
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    It doesn't necessarily feed back on itself
    the way we did things.
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    But it worked.
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    CA: So these different predictive schemes
    can be really quite wild and unexpected.
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    I mean, you looked at everything, right?
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    You looked at the weather,
    length of dresses, political opinion.
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    JS: Yes, length of dresses we didn't try.
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    CA: What sort of things?
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    JS: Well, everything.
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    Everything is grist for the mill --
    except hem lengths.
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    Weather, annual reports,
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    quarterly reports, historic data itself,
    volumes, you name it.
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    Whatever there is.
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    We take in terabytes of data a day.
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    And store it away and massage it
    and get it ready for analysis.
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    You're looking for anomalies.
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    You're looking for -- like you said,
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    the efficient market
    hypothesis is not correct.
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    CA: But any one anomaly
    might be just a random thing.
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    So, is the secret here to just look
    at multiple strange anomalies,
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    and see when they align?
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    JS: Any one anomaly
    might be a random thing;
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    however, if you have enough data
    you can tell that it's not.
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    You can see an anomaly that's persistent
    for a sufficiently long time --
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    the probability of it being
    random is not high.
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    But these things fade after a while;
    anomalies can get washed out.
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    So you have to keep on top
    of the business.
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    CA: A lot of people look
    at the hedge fund industry now
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    and are sort of ... shocked by it,
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    by how much wealth is created there,
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    and how much talent is going into it.
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    Do you have any worries
    about that industry,
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    and perhaps the financial
    industry in general?
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    Kind of being on a runaway train that's --
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    I don't know --
    helping increase inequality?
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    How would you champion what's happening
    in the hedge fund industry?
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    JS: I think in the last
    three of four years,
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    hedge funds have not done especially well.
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    We've done dandy,
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    but the hedge fund industry as a whole
    has not done so wonderfully.
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    The stock market has been on a roll,
    going up as everybody knows,
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    and price-earnings ratios have grown.
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    So an awful lot of the wealth
    that's been created in the last --
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    let's say, five or six years --
    has not been created by hedge funds.
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    People would ask me,
    "What's a hedge fund?"
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    And I'd say, "One and 20."
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    Which means -- now it's two and 20 --
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    it's two percent fixed fee
    and 20 percent of profits.
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    Hedge funds are all
    different kinds of creatures.
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    CA: Rumor has it you charge
    slightly higher fees than that.
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    JS: We charged the highest fees
    in the world at one time.
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    Five and 44, that's what we charge.
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    CA: Five and 44.
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    So five percent flat,
    44 percent of upside.
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    You still made your investors
    spectacular amounts of money.
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    JS: We made good returns, yes.
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    People got very mad:
    "How can you charge such high fees?"
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    I said, "OK, you can withdraw."
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    But "How can I get more?"
    was what people were --
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    (Laughter)
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    But at a certain point,
    as I think I told you,
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    we bought out all the investors
    because there's a capacity to the fund.
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    CA: But should we worry
    about the hedge fund industry
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    attracting too much of the world's
    great mathematical and other talent
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    to work on that, as opposed
    to the many other problems in the world?
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    JS: Well, it's not just mathematical.
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    We hire astronomers and physicists
    and things like that.
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    I don't think we should worry
    about it too much.
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    It's still a pretty small industry.
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    And in fact, bringing science
    into the investing world
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    has improved that world.
  • 16:30 - 16:34
    It's reduced volatility.
    It's increased liquidity.
  • 16:34 - 16:37
    Spreads are narrower because
    people are trading that kind of stuff.
  • 16:37 - 16:42
    So I'm not too worried about Einstein
    going off and starting a hedge fund.
  • 16:42 - 16:47
    CA: You're at a phase in your life now
    where you're actually investing, though,
  • 16:47 - 16:50
    at the other end of the supply chain --
  • 16:50 - 16:55
    you're actually boosting
    mathematics across America.
  • 16:55 - 16:56
    This is your wife, Marilyn.
  • 16:56 - 17:01
    You're working on
    philanthropic issues together.
  • 17:01 - 17:02
    Tell me about that.
  • 17:02 - 17:06
    JS: Well, Marilyn started --
  • 17:06 - 17:10
    there she is up there,
    my beautiful wife --
  • 17:10 - 17:13
    she started the foundation
    about 20 years ago.
  • 17:13 - 17:14
    I think '94.
  • 17:14 - 17:16
    I claim it was '93, she says it was '94,
  • 17:16 - 17:18
    but it was one of those two years.
  • 17:18 - 17:21
    (Laughter)
  • 17:21 - 17:27
    We started the foundation,
    just as a convenient way to give charity.
  • 17:28 - 17:31
    She kept the books, and so on.
  • 17:31 - 17:38
    We did not have a vision at that time,
    but gradually a vision emerged --
  • 17:38 - 17:43
    which was to focus on math and science,
    to focus on basic research.
  • 17:44 - 17:46
    And that's what we've done.
  • 17:46 - 17:53
    Six years ago or so, I left Renaissance
    and went to work at the foundation.
  • 17:53 - 17:54
    So that's what we do.
  • 17:54 - 17:57
    CA: And so Math for America
    is basically investing
  • 17:57 - 18:00
    in math teachers around the country,
  • 18:00 - 18:04
    giving them some extra income,
    giving them support and coaching.
  • 18:04 - 18:07
    And really trying
    to make that more effective
  • 18:07 - 18:09
    and make that a calling
    to which teachers can aspire.
  • 18:09 - 18:14
    JS: Yeah -- instead of beating up
    the bad teachers,
  • 18:14 - 18:19
    which has created morale problems
    all through the educational community,
  • 18:19 - 18:22
    in particular in math and science,
  • 18:22 - 18:28
    we focus on celebrating the good ones
    and giving them status.
  • 18:28 - 18:31
    Yeah, we give them extra money,
    15,000 dollars a year.
  • 18:31 - 18:35
    We have 800 math and science teachers
    in New York City in public schools today,
  • 18:35 - 18:37
    as part of a core.
  • 18:37 - 18:41
    There's a great morale among them.
  • 18:41 - 18:43
    They're staying in the field.
  • 18:43 - 18:46
    Next year, it'll be 1,000
    and that'll be 10 percent
  • 18:46 - 18:50
    of the math and science teachers
    in New York public schools.
  • 18:50 - 18:56
    (Applause)
  • 18:56 - 18:59
    CA: Jim, here's another project
    that you've supported philanthropically:
  • 18:59 - 19:02
    Research into origins of life, I guess.
  • 19:02 - 19:03
    What are we looking at here?
  • 19:04 - 19:05
    Well, I'll save that for a second.
  • 19:05 - 19:08
    And then I'll tell you
    what you're looking at.
  • 19:08 - 19:11
    Origins of life is a fascinating question.
  • 19:11 - 19:12
    How did we get here?
  • 19:13 - 19:15
    Well, there are two questions:
  • 19:15 - 19:21
    One is, what is the route
    from geology to biology --
  • 19:21 - 19:22
    how did we get here?
  • 19:22 - 19:25
    And the other question is,
    what did we start with?
  • 19:25 - 19:28
    What material, if any,
    did we have to work with on this route?
  • 19:28 - 19:31
    Those are two very,
    very interesting questions.
  • 19:32 - 19:38
    The first question is a tortuous path
    from geology up to RNA
  • 19:38 - 19:40
    or something like that --
    how did that all work?
  • 19:40 - 19:42
    And the other,
    what do we have to work with?
  • 19:42 - 19:44
    Well, more than we think.
  • 19:44 - 19:49
    So what's pictured there
    is a star in formation.
  • 19:50 - 19:53
    Now, every year in our Milky Way,
    which has 100 billion stars,
  • 19:53 - 19:56
    about two new stars are created.
  • 19:56 - 19:58
    Don't ask me how, but they're created.
  • 19:58 - 20:01
    And it takes them about a million
    years to settle out.
  • 20:02 - 20:04
    So, in steady state,
  • 20:04 - 20:08
    there are about two million stars
    in formation at any time.
  • 20:08 - 20:12
    That one is somewhere
    along this settling-down period.
  • 20:12 - 20:15
    And there's all this crap
    sort of circling around it,
  • 20:15 - 20:17
    dust and stuff.
  • 20:17 - 20:21
    And it'll form probably a solar system,
    or whatever it forms.
  • 20:21 - 20:23
    But here's the thing --
  • 20:23 - 20:29
    in this dust that surrounds a forming star
  • 20:29 - 20:35
    have been found, now,
    significant organic molecules.
  • 20:36 - 20:42
    Molecules not just like methane,
    but formaldehyde and cyanide --
  • 20:42 - 20:49
    things that are the building blocks --
    the seeds, if you will -- of life.
  • 20:49 - 20:52
    So, that may be typical.
  • 20:52 - 20:59
    And it may be typical
    that planets around the universe
  • 20:59 - 21:03
    start off with some of these
    basic building blocks.
  • 21:04 - 21:07
    Now does that mean
    there's going to be life all around?
  • 21:07 - 21:08
    Maybe.
  • 21:08 - 21:12
    But it's a question
    of how tortuous this path is
  • 21:12 - 21:17
    from those frail beginnings,
    those seeds, all the way to life.
  • 21:17 - 21:22
    And most of those seeds
    will fall on fallow planets.
  • 21:22 - 21:23
    CA: So for you, personally,
  • 21:23 - 21:26
    finding an answer to this question
    of where we came from,
  • 21:26 - 21:30
    of how did this thing happen,
    that is something you would love to see.
  • 21:30 - 21:31
    JS: Would love to see.
  • 21:31 - 21:33
    And like to know --
  • 21:33 - 21:38
    if that path is tortuous enough,
    and so improbable,
  • 21:38 - 21:43
    that no matter what you start with,
    we could be a singularity.
  • 21:43 - 21:44
    But on the other hand,
  • 21:45 - 21:48
    given all this organic dust
    that's floating around,
  • 21:48 - 21:52
    we could have lots of friends out there.
  • 21:53 - 21:54
    It'd be great to know.
  • 21:54 - 21:58
    CA: Jim, a couple of years ago,
    I got the chance to speak with Elon Musk,
  • 21:58 - 22:00
    and I asked him the secret of his success,
  • 22:00 - 22:04
    and he said taking
    physics seriously was it.
  • 22:05 - 22:09
    Listening to you, what I hear you saying
    is taking math seriously,
  • 22:09 - 22:12
    that has infused your whole life.
  • 22:12 - 22:17
    It's made you an absolute fortune,
    and now it's allowing you to invest
  • 22:17 - 22:21
    in the futures of thousands and thousands
    of kids across America and elsewhere.
  • 22:22 - 22:24
    Could it be that science actually works?
  • 22:24 - 22:27
    That math actually works?
  • 22:27 - 22:32
    JS: Well, math certainly works.
    Math certainly works.
  • 22:32 - 22:33
    But this has been fun.
  • 22:33 - 22:38
    Working with Marilyn and giving it away
    has been very enjoyable.
  • 22:38 - 22:41
    CA: I just find it --
    it's an inspirational thought to me,
  • 22:41 - 22:45
    that by taking knowledge seriously,
    so much more can come from it.
  • 22:45 - 22:48
    So thank you for your amazing life,
    and for coming here to TED.
  • 22:48 - 22:49
    Thank you.
  • 22:49 - 22:50
    Jim Simons!
  • 22:50 - 22:54
    (Applause)
Title:
The mathematician who cracked Wall Street
Speaker:
Jim Simons
Description:

more » « less
Video Language:
English
Team:
closed TED
Project:
TEDTalks
Duration:
23:03
  • Well, I'll save that for a second.
    ->
    JS: Well, I'll save that for a second.

    JS: I think in the last
    three of four years,
    ->
    JS: I think in the last
    three or four years,

  • Thank you, Yasush! The corrections have been made.

  • *Please note the following updates to the English subtitles as of 9/13/15:

    14:43 - 14:45

    JS: I think in the last
    three OR four years,

    19:04 - 19:05

    JS: Well, I'll save that for a second. (speaker's initials were previously missing)

  • Please note error on line 6:47, which must be the following:

    Vertices minus edges PLUS FACES come out to zero - (16-32+16=0)

    Jim Simons speaks too fast...

  • 6:46:53
    Vertices minus edges comes out to be zero. -> Vertices minus edges plus faces comes out to be zero.

    You can see it in the presentation and also calculating it.

English subtitles

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