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I found this question a while ago on a SAT practice exam or something, can't quite remember. So given an acute triangle $ABC$ with $P$ a point inside it and $AP$, $BP$, and $CP$ meeting the opposite sides at $D$, $E$, and $F$ respectively:

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How can you find the area of triangle $ABC$ given the areas of triangles $x$, $y$, and $z$?

3 Answers 3

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This was not likely to have been an SAT practice problem, though it is a typical contest problem.

$AE:EC = x:y$ (since those two triangles have the same altitude to $AC$, the ratios of their areas is the ratios of their bases with respect to that altitude) and $AP:PD = (x+y):z$ (same idea as $AE:EC$). Knowing these two ratios, apply the technique of mass points, putting masses $zy$ at $A, zx$ at $C$ (gives the ratio $x:y$ for $AE:EC$), and $y(x+y)$ at $D$ (gives $(x+y):z$ for $AP:PD$). This results in a mass of $y(x+y)-zx$ at $B$, so the ratio $BD:DC = zx:(y(x+y)-zx).$ This must also be the ratio of the areas of △ABD to △ADC (common altitude again), so (area of △ABD):$(x+y+z) = zx:(y(x+y)-zx)$. Solving from there is a matter of bashing out the algebra.

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    Bashing out the algebra: (Total area)/(x+y+z) = 1 + (△ABD)/(x+y+z) = (y(x+y)-zx+zx)/(y(x+y)-zx), so the area is $(x+y+z)y(x+y)/(y(x+y)-zx))$. This is the same as the other answer, which is great.2010-07-31
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    Wow, mass point geometry is cool2010-07-31
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Method 1: We can perform an affine transformation to make ADC any triangle we wish, while preserving colinearality and the ratios of areas. In particular, this allows us to assign exact coordinates to A, D and C. We can then use the ratio of x and y to find E and the ratio of z and x+y+z to find P. We can then use these coordinates to find B. Once we know B, we know the ratio of BC to DC and hence the ratio of the area of the whole triangle to the known areas.

Method 2: Let Q be the area of the whole triangle

AE:EC=x:y=|AEB|:|BEC|
|APB|=xQ/(x+y)-x
|BPD|=yQ/(x+y)-y-z
Now AP:PD=x+y:z
z(xQ/(x+y)-x)=(x+y)(yQ/(x+y)-y-z)
Q(zx/(x+y)-y)=xz-xy-y^2-xz-yz=-xy-y^2-xz
Q(zx-xy-y^2)/(x+y)=(-xy-y^2-xz)
Q=(-xy-y^2-xz)*(x+y)/(zx-xy-y^2)
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    So what's the area? :-)2010-07-31
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    @ShreevataR: Tried to calculate the area. Hopefully its correct, although I'd expect a problem like this to have a neater solution2010-07-31
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    In method 2, for clarity, you probably should use something other than P for the area (I'd use k), since P is also a point.2010-07-31
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As an alternative to mass points or affine transformations, you could also use an almost purely algebraic approach. Let $a$ be the area of the top gray triangle, let $b$ be the area of the middle gray triangle, and $c$ the area of the bottom gray triangle.

The fact that $|EA|/|EC| = K(BEA)/K(BCE) = K(PEA)/K(PEC)$ is expressed algebraically as $$ \frac{a+b+x}{c+y+z} = \frac{x}{y}. $$ The fact that $|BD|/|DC| = K(BDA)/K(DCA) = K(BDP)/K(DCP)$ is expressed algebraically as $$ \frac{a+b+c}{x+y+z} = \frac{c}{z}. $$

Defining the additional variables $u=a+b+c$ and $v=a+b$ (making $c=u-v$) makes this a system of two linear equations in the two unknowns $u$ and $v$: $$ \begin{align} (v+x)y &= x(u-v+y+z) \\ uz &= (u-v)(x+y+z). \end{align} $$ Solving for $u$ yields $$ u = \frac{xz(x+y+z)}{xy+y^2-xz}. $$ The total area is $u+x+y+z.$