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So why do we learn mathematics?
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Essentially, for three reasons:
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calculation,
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application,
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and last, and unfortunately least
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in terms of the time we give it,
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inspiration.
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Mathematics is the science of patterns,
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and we study it to learn how to think logically,
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critically, and creatively,
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but too much of the mathematics
that we learn in school
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is not effectively motivated,
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and when our students ask,
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"Why are we learning this?"
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then they often hear that they'll need it
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in an upcoming math class or on a future test.
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But wouldn't it be great
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if every once in a while we did mathematics
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simply because it was fun or beautiful
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or because it excited the mind?
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Now, I know many people have not
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had the opportunity to see how this can happen,
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so let me give you a quick example
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with my favorite collection of numbers,
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the Fibonacci numbers.
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(Applause)
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Yeah! I already have Fibonacci fans here.
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That's great.
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Now these numbers can be appreciated
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in many different ways.
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From the standpoint of calculation,
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they're as easy to understand
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as one plus one, which is two.
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Then one plus two is three,
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two plus three is five, three plus five is eight,
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and so on.
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Indeed, the person we call Fibonacci
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was actually named Leonardo of Pisa,
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and these numbers appear in his book "Liber Abaci,"
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which taught the Western world
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the methods of arithmetic that we use today.
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In terms of amplications,
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Fibonacci numbers appear in nature
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surprisingly often.
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The number of petals on a flower
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is typically a Fibonacci number,
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or the number of spirals on a sunflower
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or a pineapple
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tends to be a Fibonacci number as well.
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In fact, there are many more
applications of Fibonacci numbers,
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but what I find most inspirational about them
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are the beautiful number patterns they display.
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Let me show you one of my favorites.
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Suppose you like to square numbers,
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and frankly, who doesn't?
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(Laughter)
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Let's look at the squares
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of the first few Fibonacci numbers.
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Okay? So one squared is one,
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two squared is four, three squared is nine,
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five squared is 25, and so on.
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All right? Now, it's no surprise
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that when you add consecutive Fibonacci numbers,
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you get the next Fibonacci number. Right?
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That's how they're created.
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But you wouldn't expect anything special
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to happen when you add the squares together.
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But check this out.
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One plus one gives us two,
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and one plus four gives us five.
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And four plus nine is 13,
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nine plus 25 is 34,
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and yes, the pattern continues.
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In fact, here's another one.
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Suppose you wanted to look at
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adding the squares of
the first few Fibonacci numbers.
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Let's see what we get there.
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So one plus one plus four is six.
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Add nine to that, we get 15.
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Add 25, we get 40.
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Add 64, we get 104.
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Now look at those numbers.
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Those are not Fibonacci numbers,
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but if you look at them closely,
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you'll see the Fibonacci numbers
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buried inside of them.
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Do you see it? I'll show it to you.
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Six is two times three, 15 is three times five,
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40 is five times eight,
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two, three, five, eight, who do we appreciate?
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(Laughter)
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Fibonacci! Of course.
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Now, as much fun as it is to discover these patterns,
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it's even more satisfying to understand
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why they are true.
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Let's look at that last equation.
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Why should the squares of one, one,
two, three, five, and eight
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add up to eight times 13?
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I'll show you by drawing a simple picture.
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All right? We'll start with a one-by-one square
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and next to that put another one-by-one square.
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Together, they form a one-by-two rectangle.
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Beneath that, I'll put a two-by-two square,
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and next to that, a three-by-three square,
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beneath that, a five-by-five square,
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and then an eight-by-eight square,
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creating one giant rectangle, right?
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Now let me ask you a simple question:
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what is the area of the rectangle?
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Well, on the one hand,
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it's the sum of the areas
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of the squares inside it, right?
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Just as we created it.
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It's one squared plus one squared
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plus two squared plus three squared
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plus five squared plus eight squared. Right?
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That's the area.
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On the other hand, because it's a rectangle,
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the area is equal to its height times its base,
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and the height is clearly eight,
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and the base is five plus eight,
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which is the next Fibonacci number, 13. Right?
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So the area is also eight times 13.
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Since we've correctly calculated the area
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two different ways,
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they have to be the same number,
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and that's why the squares of one,
one, two, three, five, and eight
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add up to eight times 13.
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Now, if we continue this process,
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we'll generate rectangles of the form 13 by 21,
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21 by 34, and so on.
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Now check this out.
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If you divide 13 by eight,
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you get 1.625.
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And if you divide the larger number
by the smaller number,
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then these ratios get closer and closer
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to about 1.618,
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known to many people as the Golden Ratio,
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a number which has fascinated mathematicians,
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scientists, and artists for centuries.
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Now, I show all this to you because,
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like so much of mathematics,
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there's a beautiful side to it
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that I fear does not get enough attention
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in our schools.
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We spend lots of time learning about calculation,
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but let's not forget about application,
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including, perhaps, the most
important application of all,
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learning how to think.
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If I could summarize this in one sentence,
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it would be this:
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mathematics is not just solving for x,
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it's also figuring out why.
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Thank you very much.
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(Applause)
closed TED
