Difference between revisions of "1990 AIME Problems/Problem 14"

m (Solution)
Line 41: Line 41:
 
From here we just need to perform some brutish calculations. Using the formula <math>A = 18\sqrt{133} = \frac{abc}{4R}</math> (where <math>R</math> is the [[circumradius]]), we find <math>R = \frac{12\sqrt{3} \cdot (13\sqrt{3})^2}{4\cdot 18\sqrt{133}} = \frac{13^2\sqrt{3}}{2\sqrt{133}}</math> (there are slightly [[Law of Sines|simpler ways]] to calculate <math>R</math> since we have an isosceles triangle). By the Pythagorean Theorem,  
 
From here we just need to perform some brutish calculations. Using the formula <math>A = 18\sqrt{133} = \frac{abc}{4R}</math> (where <math>R</math> is the [[circumradius]]), we find <math>R = \frac{12\sqrt{3} \cdot (13\sqrt{3})^2}{4\cdot 18\sqrt{133}} = \frac{13^2\sqrt{3}}{2\sqrt{133}}</math> (there are slightly [[Law of Sines|simpler ways]] to calculate <math>R</math> since we have an isosceles triangle). By the Pythagorean Theorem,  
  
<center><math>\begin{align*}h^2 &= PA^2 - R^2 \
+
<cmath>
 +
\begin{align*}h^2 &= PA^2 - R^2 \
 
&= \left(\frac{\sqrt{939}}{2}\right)^2 - \left(\frac{13^2\sqrt{3}}{2\sqrt{133}}\right)^2\
 
&= \left(\frac{\sqrt{939}}{2}\right)^2 - \left(\frac{13^2\sqrt{3}}{2\sqrt{133}}\right)^2\
 
&= \frac{939 \cdot 133 - 13^4 \cdot 3}{4 \cdot 133} = \frac{13068 \cdot 3}{4 \cdot 133} = \frac{99^2}{133}\
 
&= \frac{939 \cdot 133 - 13^4 \cdot 3}{4 \cdot 133} = \frac{13068 \cdot 3}{4 \cdot 133} = \frac{99^2}{133}\
 
h &= \frac{99}{\sqrt{133}}
 
h &= \frac{99}{\sqrt{133}}
\end{align*}</math></center>
+
\end{align*}
 +
</cmath>
  
 
Finally, we substitute <math>h</math> into the volume equation to find <math>V = 6\sqrt{133}\left(\frac{99}{\sqrt{133}}\right) = \boxed{594}</math>.
 
Finally, we substitute <math>h</math> into the volume equation to find <math>V = 6\sqrt{133}\left(\frac{99}{\sqrt{133}}\right) = \boxed{594}</math>.
Line 52: Line 54:
 
Let <math>\triangle{ABC}</math> (or the triangle with sides <math>12\sqrt {3}</math>, <math>13\sqrt {3}</math>, <math>13\sqrt {3}</math>) be the base of our tetrahedron. We set points <math>C</math> and <math>D</math> as <math>(6\sqrt {3}, 0, 0)</math> and <math>( - 6\sqrt {3}, 0, 0)</math>, respectively. Using Pythagoras, we find <math>A</math> as <math>(0, \sqrt {399}, 0)</math>. We know that the [[vertex]] of the tetrahedron (<math>P</math>) has to be of the form <math>(x, y, z)</math>, where <math>z</math> is the [[altitude]] of the tetrahedron. Since the distance from <math>P</math> to points <math>A</math>, <math>B</math>, and <math>C</math> is <math>\frac {\sqrt {939}}{2}</math>, we can write three equations using the [[distance formula]]:
 
Let <math>\triangle{ABC}</math> (or the triangle with sides <math>12\sqrt {3}</math>, <math>13\sqrt {3}</math>, <math>13\sqrt {3}</math>) be the base of our tetrahedron. We set points <math>C</math> and <math>D</math> as <math>(6\sqrt {3}, 0, 0)</math> and <math>( - 6\sqrt {3}, 0, 0)</math>, respectively. Using Pythagoras, we find <math>A</math> as <math>(0, \sqrt {399}, 0)</math>. We know that the [[vertex]] of the tetrahedron (<math>P</math>) has to be of the form <math>(x, y, z)</math>, where <math>z</math> is the [[altitude]] of the tetrahedron. Since the distance from <math>P</math> to points <math>A</math>, <math>B</math>, and <math>C</math> is <math>\frac {\sqrt {939}}{2}</math>, we can write three equations using the [[distance formula]]:
  
<center><math>\begin{eqnarray*}
+
<cmath>
x^{2} + (y - \sqrt {399})^{2} + z^{2} &=& \frac {939}{4}\
+
\begin{align*}
(x - 6\sqrt {3})^{2} + y^{2} + z^{2} &=& \frac {939}{4}\
+
x^{2} + (y - \sqrt {399})^{2} + z^{2} &= \frac {939}{4}\
(x + 6\sqrt {3})^{2} + y^{2} + z^{2} &=& \frac {939}{4}
+
(x - 6\sqrt {3})^{2} + y^{2} + z^{2} &= \frac {939}{4}\
\end{eqnarray*}</math></center>
+
(x + 6\sqrt {3})^{2} + y^{2} + z^{2} &= \frac {939}{4}
 +
\end{align*}
 +
</cmath>
  
 
Subtracting the last two equations, we get <math>x = 0</math>. Solving for <math>y,z</math> with a bit of effort, we eventually get <math>x = 0</math>, <math>y = \frac {291}{2\sqrt {399}}</math>, <math>z = \frac {99}{\sqrt {133}}</math>.
 
Subtracting the last two equations, we get <math>x = 0</math>. Solving for <math>y,z</math> with a bit of effort, we eventually get <math>x = 0</math>, <math>y = \frac {291}{2\sqrt {399}}</math>, <math>z = \frac {99}{\sqrt {133}}</math>.

Revision as of 17:38, 10 March 2015

Problem

The rectangle $ABCD^{}_{}$ below has dimensions $AB^{}_{} = 12 \sqrt{3}$ and $BC^{}_{} = 13 \sqrt{3}$. Diagonals $\overline{AC}$ and $\overline{BD}$ intersect at $P^{}_{}$. If triangle $ABP^{}_{}$ is cut out and removed, edges $\overline{AP}$ and $\overline{BP}$ are joined, and the figure is then creased along segments $\overline{CP}$ and $\overline{DP}$, we obtain a triangular pyramid, all four of whose faces are isosceles triangles. Find the volume of this pyramid.

AIME 1990 Problem 14.png

Solution

Solution 1

import three; pointpen = black; pathpen = black+linewidth(0.7); pen small = fontsize(9);
currentprojection = perspective(20,-20,12);
triple O=(0,0,0),A=(0,399^.5,0),D=(108^.5,0,0),C=(-108^.5,0,0);
pair CENTER=circumcenter((A.x,A.y),(C.x,C.y),(D.x,D.y));
triple P=(CENTER.x,CENTER.y,99/133^.5); /*, Pa=(P.x,P.y,0); 
D(P--Pa--A);D(C--Pa--D); */
D((C+D)/2--A--C--D--P--C--P--A--D);
MP("A",A,NE);MP("P",P,N);MP("C",C);MP("D",D);
MP("13\sqrt{3}",(A+D)/2,E,small);MP("13\sqrt{3}",(A+C)/2,N,small);MP("12\sqrt{3}",(C+D)/2,SW,small);
 (Error making remote request. Unknown error_msg)

Our triangular pyramid has base $12\sqrt{3} - 13\sqrt{3} - 13\sqrt{3} \triangle$. The area of this isosceles triangle is easy to find by $[ACD] = \frac{1}{2}bh$, where we can find $h_{ACD}$ to be $\sqrt{399}$ by the Pythagorean Theorem. Thus $A = \frac 12(12\sqrt{3})\sqrt{399} = 18\sqrt{133}$.

<center>
size(280);
import three; pointpen = black; pathpen = black+linewidth(0.7); pen small = fontsize(9);
real h=169/2*(3/133)^.5; currentprojection = perspective(20,-20,12);
triple O=(0,0,0),A=(0,399^.5,0),D=(108^.5,0,0),C=(-108^.5,0,0);
pair CENTER=circumcenter((A.x,A.y),(C.x,C.y),(D.x,D.y));
triple P=(CENTER.x,CENTER.y,99/133^.5), Pa=(P.x,P.y,0);
D(A--C--D--P--C--P--A--D);
D(P--Pa--A);D(C--Pa--D);D(circle(Pa,h));
MP("A",A,NE);MP("C",C,NW);MP("D",D);MP("P",P,N);MP("P'",Pa,SW);
MP("13\sqrt{3}",(A+D)/2,E,small);MP("13\sqrt{3}",(A+C)/2,NW,small);MP("12\sqrt{3}",(C+D)/2,SW,small);
MP("h",(P--Pa)/2,W);MP("\frac{\sqrt{939}}2",(C+P)/2,NW);
 (Error making remote request. Unknown error_msg)

To find the volume, we want to use the equation $\frac 13Bh = 6\sqrt{133}h$, so we need to find the height of the tetrahedron. By the Pythagorean Theorem, $AP = CP = DP = \frac{\sqrt{939}}{2}$. If we let $P$ be the center of a sphere with radius $\frac{\sqrt{939}}{2}$, then $A,C,D$ lie on the sphere. The cross section of the sphere that contains $A,C,D$ is a circle, and the center of that circle is the foot of the perpendicular from the center of the sphere. Hence the foot of the height we want to find occurs at the circumcenter of $\triangle ACD$.

From here we just need to perform some brutish calculations. Using the formula $A = 18\sqrt{133} = \frac{abc}{4R}$ (where $R$ is the circumradius), we find $R = \frac{12\sqrt{3} \cdot (13\sqrt{3})^2}{4\cdot 18\sqrt{133}} = \frac{13^2\sqrt{3}}{2\sqrt{133}}$ (there are slightly simpler ways to calculate $R$ since we have an isosceles triangle). By the Pythagorean Theorem,

\begin{align*}h^2 &= PA^2 - R^2 \\ &= \left(\frac{\sqrt{939}}{2}\right)^2 - \left(\frac{13^2\sqrt{3}}{2\sqrt{133}}\right)^2\\ &= \frac{939 \cdot 133 - 13^4 \cdot 3}{4 \cdot 133} = \frac{13068 \cdot 3}{4 \cdot 133} = \frac{99^2}{133}\\ h &= \frac{99}{\sqrt{133}} \end{align*}

Finally, we substitute $h$ into the volume equation to find $V = 6\sqrt{133}\left(\frac{99}{\sqrt{133}}\right) = \boxed{594}$.

Solution 2

Let $\triangle{ABC}$ (or the triangle with sides $12\sqrt {3}$, $13\sqrt {3}$, $13\sqrt {3}$) be the base of our tetrahedron. We set points $C$ and $D$ as $(6\sqrt {3}, 0, 0)$ and $( - 6\sqrt {3}, 0, 0)$, respectively. Using Pythagoras, we find $A$ as $(0, \sqrt {399}, 0)$. We know that the vertex of the tetrahedron ($P$) has to be of the form $(x, y, z)$, where $z$ is the altitude of the tetrahedron. Since the distance from $P$ to points $A$, $B$, and $C$ is $\frac {\sqrt {939}}{2}$, we can write three equations using the distance formula:

\begin{align*} x^{2} + (y - \sqrt {399})^{2} + z^{2} &= \frac {939}{4}\\ (x - 6\sqrt {3})^{2} + y^{2} + z^{2} &= \frac {939}{4}\\ (x + 6\sqrt {3})^{2} + y^{2} + z^{2} &= \frac {939}{4} \end{align*}

Subtracting the last two equations, we get $x = 0$. Solving for $y,z$ with a bit of effort, we eventually get $x = 0$, $y = \frac {291}{2\sqrt {399}}$, $z = \frac {99}{\sqrt {133}}$. Since the area of a triangle is $\frac {1}{2}\cdot bh$, we have the base area as $18\sqrt {133}$. Thus, the volume is $V = \frac {1}{3}\cdot18\sqrt {133}\cdot\frac {99}{\sqrt {133}} = 6\cdot99 = 594$.

See also

1990 AIME (ProblemsAnswer KeyResources)
Preceded by
Problem 13
Followed by
Problem 15
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
All AIME Problems and Solutions

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