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# Heron's formula

Video transcript

I think it's pretty common
knowledge how to find the area of the triangle if we know the
length of its base and its height. So, for example, if that's my
triangle, and this length right here-- this base-- is of length
b and the height right here is of length h, it's pretty common
knowledge that the area of this triangle is going to be equal
to 1/2 times the base times the height. So, for example, if the base
was equal to 5 and the height was equal to 6, then our area
would be 1/2 times 5 times 6, which is 1/2 times 30--
which is equal to 15. Now what is less well-known is
how to figure out the area of a triangle when you're only given
the sides of the triangle. When you aren't
given the height. So, for example, how do
you figure out a triangle where I just give you the
lengths of the sides. Let's say that's side a, side
b, and side c. a, b, and c are the lengths of these sides. How do you figure that out? And to do that we're
going to apply something called Heron's Formula. And I'm not going to
prove it in this video. I'm going to prove it
in a future video. And really to prove it you
already probably have the tools necessary. It's really just the
Pythagorean theorem and a lot of hairy algebra. But I'm just going to show you
the formula now and how to apply it, and then you'll
hopefully appreciate that it's pretty simple and pretty
easy to remember. And it can be a nice trick
to impress people with. So Heron's Formula says first
figure out this third variable S, which is essentially
the perimeter of this triangle divided by 2. a plus b plus c, divided by 2. Then once you figure out S, the
area of your triangle-- of this triangle right there-- is going
to be equal to the square root of S-- this variable S right
here that you just calculated-- times S minus a, times S
minus b, times S minus c. That's Heron's
Formula right there. This combination. Let me square it off for you. So that right there
is Heron's Formula. And if that looks a little bit
daunting-- it is a little bit more daunting, clearly, than
just 1/2 times base times height. Let's do it with an actual
example or two, and actually see this is actually
not so bad. So let's say I have a triangle. I'll leave the
formula up there. So let's say I have a
triangle that has sides of length 9, 11, and 16. So let's apply Heron's Formula. S in this situation is going to
be the perimeter divided by 2. So 9 plus 11 plus
16, divided by 2. Which is equal to 9 plus
11-- is 20-- plus 16 is 36, divided by 2 is 18. And then the area by Heron's
Formula is going to be equal to the square root of S-- 18--
times S minus a-- S minus 9. 18 minus 9, times 18 minus
11, times 18 minus 16. And then this is equal to
the square root of 18 times 9 times 7 times 2. Which is equal to-- let's
see, 2 times 18 is 36. So I'll just
rearrange it a bit. This is equal to the square
root of 36 times 9 times 7, which is equal to the square
root of 36 times the square root of 9 times the
square root of 7. The square root
of 36 is just 6. This is just 3. And we don't deal with the
negative square roots, because you can't have
negative side lengths. And so this is going to
be equal to 18 times the square root of 7. So just like that, you saw it,
it only took a couple of minutes to apply Heron's
Formula, or even less than that, to figure out that the
area of this triangle right here is equal to 18
square root of seven. Anyway, hopefully you
found that pretty neat.