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What do Euclid,
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twelve-year-old Einstein,
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and American President James Garfield
have in common?
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They all came up with elegant
proofs for the famous Pythagorean Theorem,
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the rule that says for a right triangle,
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the square of one side plus
the square of the other side
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is equal to the square of the hypotenuse.
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In other words, a²+b²=c².
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This statement is one of the most
fundamental rules of geometry,
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and the basis for practical applications,
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like constructing stable buildings
and triangulating GPS coordinates.
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The theorem is named for Pythagoras,
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a Greek philosopher and mathematician
in the 6th century BC,
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but it was known more than
1,000 years earlier.
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A Babylonian tablet from around 1800 BC
lists 15 sets of numbers
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that satisfy the theorem.
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Some historians speculate
that Ancient Egyptian surveyors
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used one such set of numbers, 3, 4, 5,
to make square corners.
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The theory is that surveyors could stretch
a knotted rope with twelve equal segments
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to form a triangle with sides of length
3, 4 and 5.
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According to the converse
of the Pythagorean Theorem,
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that has to make a right triangle,
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and therefore, a square corner.
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And the earliest known
Indian mathematical texts
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written between 800 and 600 BC
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state that a rope stretched across
the diagonal of a square
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produces a square twice as large
as the original one.
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That relationship can be derived
from the Pythagorean Theorem.
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But how do we know
that the theorem is true
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for every right triangle
on a flat surface,
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not just the ones these mathematicians
and surveyors knew about?
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Because we can prove it.
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Proofs use existing mathematical rules
and logic
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to demonstrate that a theorem
must hold true all the time.
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One classic proof often attributed
to Pythagoras himself
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uses a strategy called
proof by rearrangement.
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Take four identical right triangles
with side lengths a and b
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and hypotenuse length c.
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Arrange them so that their hypotenuses
form a tilted square.
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The area of that square is c².
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Now rearrange the triangle
into two rectangles,
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leaving smaller squares on either side.
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The areas of those squares
are a² and b².
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Here's the key.
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The total area of
the figure didn't change,
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and the areas of the triangles
didn't change.
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So the empty space in one, c²
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must be equal to
the empty space in the other,
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a² + b².
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Another proof comes from a fellow Greek
mathematician Euclid
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and was also stumbled upon
almost 2,000 years later
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by twelve-year-old Einstein.
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This proof divides one right triangle
into two others
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and uses the principle that if the
corresponding angles of two triangles
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are the same,
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the ratio of the other
sides is the same, too.
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So for these three similar triangles,
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you can write these expressions
for their sides.
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Next, rearrange the terms.
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And finally, add the two equations
together and simplify to get
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ab²+ac²=bc²,
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or a²+b²=c².
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Here's one that uses tessellation,
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a repeating geometric pattern
for a more visual proof.
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Can you see how it works?
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Pause the video if you'd like some time
to think about it.
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Here's the answer.
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The dark gray square is a²
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and the light gray one is b².
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The one outlined in blue is c².
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Each blue outlined square
contains the pieces of exactly one dark
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and one light gray square,
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proving the Pythagorean Theorem again.
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And if you'd really like
to convince yourself,
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you could build a turntable
with three square boxes of equal depth
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connected to each other
around a right triangle.
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If you fill the largest square with water
and spin the turntable,
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the water from the large square
will perfectly fill the two smaller ones.
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The Pythagorean Theorem has more
than 350 proofs, and counting,
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ranging from brilliant to obscure.
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Can you add your own to the mix?
closed TED
