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| A 3-4-5 triangle |
c2 = a2 + b2
I thought it would be fun to attempt to prove the theorem for myself. This post describes my solution.
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| Figure 1: Draw a right-angled triangle with squares |
1. Draw a right-angled triangle with squares
- Draw a right-angled triangle
- Draw the squares extending from each side
- Label the sides a, b and c.
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| Figure 2: Flip the square on the hypotenuse |
2. Flip the square on the hypotenuse
- Flip the square on the hypotenuse over
- Mark dotted lines to indicate the larger square containing the flipped square [1]
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| Figure 3: Label the segments |
3. Label the segments
- Mark the segments on each side of the dotted square and label as follows:
- Label the top and right segments a and b as guided by the red and green squares
- Mark the top segment on the left side b, since it is the third side of a right-angled triangle with a and hypotenuse c as the other two sides
- Mark the bottom segment on the left side a, since it is symmetrical to the right side
- Mark the right segment on the bottom side a, since it is the third side of a right-angled triangle with b and hypotenuse c as the other two sides
- Mark the left segment on the bottom side b, since it is symmetrical to the top side
4. Do some algebra
- The area of the square on the hypotenuse equals the area of the large square minus the areas of the triangles in the four corners:
c2 = (a + b)(a + b) - 4(a * b / 2)
= a2 + b2 + 2ab - 2ab
= a2 + b2
Which is the Pythagorean Theorem!
It turns out that there are over a hundred possible proofs. The above proof is similar to proof #4 which is credited to the 12th century Hindu mathematician Bhaskara II.
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| Figure 4: Side and corner collinearity |
The square in the center has a side length of (b - a). As an alternative proof, the area of the square on the hypotenuse equals the area of the center square plus the area of the four triangles:
c2 = (b - a)(b - a) + 4(a * b / 2)
= b2 + a2 - 2ab + 2ab
= a2 + b2
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