Herons Formula
Let a,b,c be the sides of a triangle, and let A be the area of the triangle. Heron's formula states that A^2 = s(s-a)(s-b)(s-c), where s = (a+b+c)/2.
Here's one derivation:
Consider the general triangle with edge lengths a,b,c shown below:
We have a = u+v, b^2 = h^2+u^2, c^2 = h^2+v^2. Subtracting the second from the third gives u^2-v^2 = b^2-c^2. Dividing both sides by a = u+v, we have u-v = (b^2-c^2)/a. Adding u+v = a to both sides and solving for u gives:
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Taking h = sqrt(b^2-u^2) we have:
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which is equivalent to Heron's formula. Factoring out 1/4, this gives three different ways of expressing (2ab)^2 - (a^2+b^2-c^2)^2 as a difference of two squares. Equivalently, it gives three different factorizations of 16A^2, each of the form
16A^2 = [(a+b)^2 - c^2] [c^2 - (a-b)^2]
Factoring each of these terms gives the explicitly symmetrical form
16A^2 = (a+b+c)(a+b-c)(c-a+b)(c+a-b)
so if we define s=(a+b+c)/2 we can rewrite the first equation as:
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which is the area formula as given by Heron.
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