Difference between revisions of "1986 AIME Problems/Problem 9"

(solution 1 = myself, solution 2 by altheman)
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[[Image:1986_AIME-9.png]]
 
[[Image:1986_AIME-9.png]]
  
Let the points at which the segments hit the triangle be called <math>D, D', E, E', F, F'</math> as shown above. First, note that all three smaller triangles created and the larger triangle are [[similar triangles|similar]] (<math>\triangle ABC \sim \triangle DPD' \sim \triangle PEE' \sim \triangle F'PF</math>). This is easy to find using repeated [[alternate interior angles]]. The remaining three sections are [[parallelogram]]s, which is also simple to see by the parallel lines.  
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Let the points at which the segments hit the triangle be called <math>D, D', E, E', F, F'</math> as shown above. All three smaller triangles and the larger triangle are [[similar triangles|similar]] (<math>\triangle ABC \sim \triangle DPD' \sim \triangle PEE' \sim \triangle F'PF</math>). This is easy to find using repeated [[alternate interior angles]]. The remaining three sections are [[parallelogram]]s, which is also simple to see by the parallel lines.  
  
Since <math>\displaystyle PDAF'</math> is a parallelogram, we find that <math>PF' = AD</math>, and similarly <math>PE = BD'</math>. So <math>d = PF' + PE' = AD + BD' = 425 - DD'</math>. Thus <math>DD' = 425 - d</math>. By the same logic, <math>EE' = 450 - d</math>.  
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Since <math>\displaystyle PDAF'</math> is a parallelogram, we find <math>PF' = AD</math>, and similarly <math>PE = BD'</math>. So <math>d = PF' + PE' = AD + BD' = 425 - DD'</math>. Thus <math>DD' = 425 - d</math>. By the same logic, <math>EE' = 450 - d</math>.  
  
 
Since <math>\triangle DPD' \sim \triangle ABC</math>, we have the [[proportion]]:
 
Since <math>\triangle DPD' \sim \triangle ABC</math>, we have the [[proportion]]:
  
<math>\frac{425-d}{425} = \frac{PD}{510}</math>
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<div style="text-align:center;"><math>\frac{425-d}{425} = \frac{PD}{510}</math><br /><math>PD = 510 - \frac{510}{425}d = 510 - \frac{6}{5}d</math></div>
 
 
<math>PD = 510 - \frac{510}{425}d = 510 - \frac{6}{5}d</math>
 
  
 
Doing the same with <math>\displaystyle \triangle PEE'</math>, we find that <math>\displaystyle PE' = \displaystyle 510 - \frac{17}{15}d \displaystyle</math>. Now, <math>d = PD + PE' = 510 - \frac{6}{5}d + 510 - \frac{17}{15}d \Longrightarrow d\left(\frac{50}{15}\right) = 1020 \Longrightarrow d = 306</math>.
 
Doing the same with <math>\displaystyle \triangle PEE'</math>, we find that <math>\displaystyle PE' = \displaystyle 510 - \frac{17}{15}d \displaystyle</math>. Now, <math>d = PD + PE' = 510 - \frac{6}{5}d + 510 - \frac{17}{15}d \Longrightarrow d\left(\frac{50}{15}\right) = 1020 \Longrightarrow d = 306</math>.

Revision as of 18:19, 12 September 2007

Problem

In $\displaystyle \triangle ABC$, $\displaystyle AB= 425$, $\displaystyle BC=450$, and $\displaystyle AC=510$. An interior point $\displaystyle P$ is then drawn, and segments are drawn through $\displaystyle P$ parallel to the sides of the triangle. If these three segments are of an equal length $\displaystyle d$, find $\displaystyle d$.

Solution

Solution 1

1986 AIME-9.png

Let the points at which the segments hit the triangle be called $D, D', E, E', F, F'$ as shown above. All three smaller triangles and the larger triangle are similar ($\triangle ABC \sim \triangle DPD' \sim \triangle PEE' \sim \triangle F'PF$). This is easy to find using repeated alternate interior angles. The remaining three sections are parallelograms, which is also simple to see by the parallel lines.

Since $\displaystyle PDAF'$ is a parallelogram, we find $PF' = AD$, and similarly $PE = BD'$. So $d = PF' + PE' = AD + BD' = 425 - DD'$. Thus $DD' = 425 - d$. By the same logic, $EE' = 450 - d$.

Since $\triangle DPD' \sim \triangle ABC$, we have the proportion:

$\frac{425-d}{425} = \frac{PD}{510}$
$PD = 510 - \frac{510}{425}d = 510 - \frac{6}{5}d$

Doing the same with $\displaystyle \triangle PEE'$, we find that $\displaystyle PE' = \displaystyle 510 - \frac{17}{15}d \displaystyle$. Now, $d = PD + PE' = 510 - \frac{6}{5}d + 510 - \frac{17}{15}d \Longrightarrow d\left(\frac{50}{15}\right) = 1020 \Longrightarrow d = 306$.

Solution 2

Define the points the same as above.

Let $[CE'PF] = a$, $[E'EP] = b$, $\displaystyle [BEPD'] = c \displaystyle$, $[D'PD] = d$, $\displaystyle [DAF'P] = e$ and $[F'D'P] = f$

Key theorem: the ratio of the areas of 2 similar triangles is the ratio of a pair of corresponding sides squared.

Let the length of the segment be $x$ and the area of the triangle be $A$, using the theorem, we get:

$\frac {c + e + d}{A} = \left(\frac {x}{BC}\right)^2$, $\displaystyle \frac {b + c + d}{A} \displaystyle = \left(\frac {x}{AC}\right)^2$, $\frac {a + b + f}{A} = \left(\frac {x}{AB}\right)^2$ adding all these together and using $a + b + c + d + e + f = A$ we get $\frac {f + d + b}{A} + 1 = x^2*\left(\frac {1}{BC^2} + \frac {1}{AC^2} + \frac {1}{AB^2}\right)$

Using corresponding angles from parallel lines, it is easy to show that $\triangle ABC \sim \triangle F'PF$, since $ADPF'$ and $CFPE'$ are parallelograms, it is easy to show that $FF' = AC - x$

Now we have the side length ratio, so we have the area ratio $\displaystyle \frac {f}{A} = \left(\frac {AC - x}{AC}\right)^2 = \left(1 - \frac {x}{AC}\right)^2$, by symmetry, we have $\displaystyle \frac {d}{A} = \left(1 - \frac {x}{AB}\right)^2$ and $\frac {b}{A} = \left(1 - \frac {x}{BC}\right)^2$

Substituting these into our initial equation, we have $1 + \sum_{cyc}\left(1 - \frac {x}{AB}\right) - \frac {x^2}{AB^2} = 0$ $1 + \sum_{cyc}1 - 2*\frac {x}{AB} = 0$ $\displaystyle \frac {2}{\frac {1}{AB} + \frac {1}{BC} + \frac {1}{CA}} = x$ answer follows after some hideous computation

See also

1986 AIME (ProblemsAnswer KeyResources)
Preceded by
Problem 8
Followed by
Problem 10
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
All AIME Problems and Solutions