Difference between revisions of "2022 AIME I Problems/Problem 10"

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Three spheres with radii <math>11</math>, <math>13</math>, and <math>19</math> are mutually externally tangent. A plane intersects the spheres in three congruent circles centered at <math>A</math>, <math>B</math>, and <math>C</math>, respectively, and the centers of the spheres all lie on the same side of this plane. Suppose that <math>AB^2 = 560</math>. Find <math>AC^2</math>.
 
Three spheres with radii <math>11</math>, <math>13</math>, and <math>19</math> are mutually externally tangent. A plane intersects the spheres in three congruent circles centered at <math>A</math>, <math>B</math>, and <math>C</math>, respectively, and the centers of the spheres all lie on the same side of this plane. Suppose that <math>AB^2 = 560</math>. Find <math>AC^2</math>.
  
== Diagrams ==
+
== Diagram ==
 +
<asy>
 +
/* Made by MRENTHUSIASM */
 +
size(300);
 +
import graph3;
 +
import solids;
  
 +
currentprojection=orthographic((7,0.2,9));
 +
triple A, B, C, OA, OB, OC;
 +
A = (0,0,0);
 +
B = (0,sqrt(560),0);
 +
C = intersectionpoints(Circle(A,sqrt(756),(0,0,1)),Circle(B,sqrt(960),(0,0,1)))[1];
 +
OA = (0,0,4);
 +
OB = (0,sqrt(560),8);
 +
OC = (C.x,C.y,16);
 +
 +
draw(shift(OC)*scale3(19)*unitsphere,green,light=Viewport);
 +
draw(shift(OA)*scale3(11)*unitsphere,red,light=Viewport);
 +
draw(shift(OB)*scale3(13)*unitsphere,yellow,light=Viewport);
 +
draw(Circle(A,sqrt(105),(0,0,1))^^Circle(B,sqrt(105),(0,0,1))^^Circle(C,sqrt(105),(0,0,1)));
 +
draw((-70,-20,0)--(-70,45,0)--(20,45,0)--(20,-20,0)--cycle);
 +
 +
dot(OA^^OB^^OC,linewidth(4.5));
 +
dot("$A$",A,(0,1,0),linewidth(4.5));
 +
dot("$B$",B,(0,1,0),linewidth(4.5));
 +
dot("$C$",C,(0,1.5,0),linewidth(4.5));
 +
</asy>
 +
~MRENTHUSIASM
 +
 +
==Solution 1==
 +
 +
This solution refers to the <b>Diagram</b> section.
 +
 +
We let <math>\ell</math> be the plane that passes through the spheres and <math>O_A</math> and <math>O_B</math> be the centers of the spheres with radii <math>11</math> and <math>13</math>. We take a cross-section that contains <math>A</math> and <math>B</math>, which contains these two spheres but not the third, as shown below:
 
<asy>
 
<asy>
 
+
size(400);
size(500);
 
 
pair A, B, OA, OB;
 
pair A, B, OA, OB;
  
 
B = (0,0);
 
B = (0,0);
 
A = (-23.6643191,0);
 
A = (-23.6643191,0);
OB = (0,-8);
+
OB = (0,8);
OA = (-23.6643191,-4);
+
OA = (-23.6643191,4);
  
 
draw(circle(OB,13));
 
draw(circle(OB,13));
Line 18: Line 49:
  
 
draw((-48,0)--(24,0));
 
draw((-48,0)--(24,0));
label("$l$",(-42,1),N);
+
label("$\ell$",(-42,0),S);
  
label("$A$",A,N);
+
label("$A$",A,S);
label("$B$",B,N);
+
label("$B$",B,S);
label("$O_A$",OA,S);
+
label("$O_A$",OA,N);
label("$O_B$",OB,S);
+
label("$O_B$",OB,N);
  
 
draw(A--OA);
 
draw(A--OA);
 
draw(B--OB);
 
draw(B--OB);
 
draw(OA--OB);
 
draw(OA--OB);
draw(OA--(0,-4));
+
draw(OA--(0,4));
 
draw(OA--(-33.9112699,0));
 
draw(OA--(-33.9112699,0));
 
draw(OB--(10.2469508,0));
 
draw(OB--(10.2469508,0));
label("$24$",midpoint(OA--OB),S);
+
label("$24$",midpoint(OA--OB),N);
label("$\sqrt{560}$",midpoint(A--B),N);
+
label("$\sqrt{560}$",midpoint(A--B),S);
label("$11$",midpoint(OA--(-33.9112699,0)),S);
+
label("$11$",midpoint(OA--(-33.9112699,0)),NW);
label("$13$",midpoint(OB--(10.2469508,0)),S);
+
label("$13$",midpoint(OB--(10.2469508,0)),NE);
label("$r$",midpoint(midpoint(A--B)--A),N);
+
label("$r$",midpoint(midpoint(A--B)--A),S);
label("$r$",midpoint(midpoint(A--B)--B),N);
+
label("$r$",midpoint(midpoint(A--B)--B),S);
label("$r$",midpoint(A--(-33.9112699,0)),N);
+
label("$r$",midpoint(A--(-33.9112699,0)),S);
label("$r$",midpoint(B--(10.2469508,0)),N);
+
label("$r$",midpoint(B--(10.2469508,0)),S);
label("$x$",midpoint(midpoint(B--OB)--OB),E);
+
label("$x$",midpoint(midpoint(B--OB)--OB),W);
 
label("$D$",midpoint(B--OB),E);
 
label("$D$",midpoint(B--OB),E);
 +
</asy>
 +
Because the plane cuts out congruent circles, they have the same radius and from the given information, <math>AB = \sqrt{560}</math>. Since <math>ABO_BO_A</math> is a trapezoid, we can drop an altitude from <math>O_A</math> to <math>BO_B</math> to create a rectangle and triangle to use Pythagorean theorem. We know that the length of the altitude is <math>\sqrt{560}</math> and let the distance from <math>O_B</math> to <math>D</math> be <math>x</math>. Then we have <math>x^2 = 576-560 \implies x = 4</math>.
  
 +
We have <math>AO_A = BD</math> because of the rectangle, so <math>\sqrt{11^2-r^2} = \sqrt{13^2-r^2}-4</math>.
 +
Squaring, we have <math>121-r^2 = 169-r^2 + 16 - 8 \cdot \sqrt{169-r^2}</math>.
 +
Subtracting, we get <math>8 \cdot \sqrt{169-r^2} = 64 \implies \sqrt{169-r^2} = 8 \implies 169-r^2 = 64 \implies r^2 = 105</math>.
 +
We also notice that since we had <math>\sqrt{169-r^2} = 8</math> means that <math>BO_B = 8</math> and since we know that <math>x = 4</math>, <math>AO_A = 4</math>.
  
 
+
We take a cross-section that contains <math>A</math> and <math>C</math>, which contains these two spheres but not the third, as shown below:
</asy>
 
 
 
 
<asy>
 
<asy>
 
+
size(400);
size(500);
+
pair A, C, OA, OC, M;
pair A, C, OA, OC;
 
  
 
C = (0,0);
 
C = (0,0);
 
A = (-27.4954541697,0);
 
A = (-27.4954541697,0);
OC = (0,-16);
+
OC = (0,16);
OA = (-27.4954541697,-4);
+
OA = (-27.4954541697,4);
 +
M = midpoint(A--C);
  
 
draw(circle(OC,19));
 
draw(circle(OC,19));
Line 60: Line 95:
  
 
draw((-48,0)--(24,0));
 
draw((-48,0)--(24,0));
label("$l$",(-42,1),N);
+
label("$\ell$",(-42,0),S);
  
label("$A$",A,N);
+
label("$A$",A,S);
label("$C$",C,N);
+
label("$C$",C,S);
label("$O_A$",OA,S);
+
label("$O_A$",OA,N);
label("$O_C$",OC,S);
+
label("$O_C$",OC,N);
  
 
draw(A--OA);
 
draw(A--OA);
 
draw(C--OC);
 
draw(C--OC);
 
draw(OA--OC);
 
draw(OA--OC);
draw(OA--(0,-4));
+
draw(OA--(0,4));
 
draw(OA--(-37.8877590151,0));
 
draw(OA--(-37.8877590151,0));
 
draw(OC--(10.2469508,0));
 
draw(OC--(10.2469508,0));
label("$30$",midpoint(OA--OC),S);
+
label("$30$",midpoint(OA--OC),NW);
label("$11$",midpoint(OA--(-37.8877590151,0)),S);
+
label("$11$",midpoint(OA--(-37.8877590151,0)),NW);
label("$19$",midpoint(OC--(10.2469508,0)),E);
+
label("$19$",midpoint(OC--(10.2469508,0)),NE);
label("$r$",midpoint(midpoint(A--C)--A),N);
+
label("$r$",midpoint(midpoint(M--A)--A),S);
label("$r$",midpoint(midpoint(A--C)--C),N);
+
label("$r$",midpoint(midpoint(M--C)--C),S);
label("$r$",midpoint(A--(-37.8877590151,0)),N);
+
label("$r$",midpoint(A--(-37.8877590151,0)),S);
label("$r$",midpoint(C--(10.2469508,0)),N);
+
label("$r$",midpoint(C--(10.2469508,0)),S);
label("$E$",(0,-4),E);
+
label("$E$",(0,4),E);
 
 
 
 
 
 
 
</asy>
 
</asy>
 
+
We have <math>CO_C = \sqrt{19^2-r^2} = \sqrt{361 - 105} = \sqrt{256} = 16</math>. Since <math>AO_A = 4</math>, we have <math>EO_C = 16-4 = 12</math>. Using Pythagorean theorem, <math>O_AE = \sqrt{30^2 - 12^2} = \sqrt{900-144} = \sqrt{756}</math>. Therefore, <math>O_AE^2 = AC^2  = \boxed{756}</math>.
==Solution 1==
 
 
 
We let <math>l</math> be the plane that passes through the spheres and <math>O_A</math> and <math>O_B</math> be the centers of the spheres with radii <math>11</math> and <math>13</math>. We take a cross-section that contains <math>A</math> and <math>B</math>, which contains these two spheres but not the third. Because the plane cuts out congruent circles, they have the same radius and from the given information, <math>AB = \sqrt{560}</math>. Since <math>ABO_BO_A</math> is a trapezoid, we can drop an altitude from <math>O_A</math> to <math>BO_B</math> to create a rectangle and triangle to use Pythagorean theorem. We know that the length of the altitude is <math>\sqrt{560}</math> and let the distance from <math>O_B</math> to <math>D</math> be <math>x</math>. Then we have <math>x^2 = 576-560 \implies x = 4</math>.
 
 
 
We have <math>AO_A = BD</math> because of the rectangle, so <math>\sqrt{11^2-r^2} = \sqrt{13^2-r^2}-4</math>.
 
Squaring, we have <math>121-r^2 = 169-r^2 + 16 - 8 \cdot \sqrt{169-r^2}</math>.
 
Subtracting, we get <math>8 \cdot \sqrt{169-r^2} = 64 \implies \sqrt{169-r^2} = 8 \implies 169-r^2 = 64 \implies r^2 = 105</math>.
 
We also notice that since we had <math>\sqrt{169-r^2} = 8</math> means that <math>BO_B = 8</math> and since we know that <math>x = 4</math>, <math>AO_A = 4</math>.
 
 
 
We now look at our second diagram.
 
 
 
<math>CO_C = \sqrt{19^2-r^2} = \sqrt{361 - 105} = \sqrt{256} = 16</math>. Since <math>AO_A = 4</math>, we have <math>EO_C = 16-4 = 12</math>. Using Pythagorean theorem, <math>O_AE = \sqrt{30^2 - 12^2} = \sqrt{900-144} = \sqrt{756}</math>. Therefore, <math>O_AE^2 = AC^2  = \boxed{756}</math>
 
  
 
~KingRavi
 
~KingRavi
  
 
==Solution 2==
 
==Solution 2==
Let the distance between the center of the sphere to the center of those circular intersections as <math>a,b,c</math> separately. <math>a-11,b-13,c-19</math>. According to the problem, we have <math>a^2-11^2=b^2-13^2=c^2-19^2;(11+13)^2-(b-a)^2=560</math>. After solving we have <math>b-a=4</math>, plug this back to <math>11^2-a^2=13^2-b^2; a=4,b=8,c=16</math>
+
Let the distance between the center of the sphere to the center of those circular intersections as <math>a,b,c</math> separately.
  
The desired value is <math>(11+19)^2-(16-4)^2=\boxed{756}</math>
+
According to the problem, we have <math>a^2-11^2=b^2-13^2=c^2-19^2; (11+13)^2-(b-a)^2=560.</math> After solving we have <math>b-a=4,</math> plug this back to <math>11^2-a^2=13^2-b^2,</math> we have <math>a=4, b=8,</math> and <math>c=16.</math>
 +
 
 +
The desired value is <math>(11+19)^2-(16-4)^2=\boxed{756}.</math>
  
 
~bluesoul
 
~bluesoul
Line 154: Line 176:
 
\begin{align*}
 
\begin{align*}
 
AC^2 & = O_A O_C^2 - \left( O_C C - O_A A \right)^2 \\
 
AC^2 & = O_A O_C^2 - \left( O_C C - O_A A \right)^2 \\
& = \boxed{\textbf{(756) }} .
+
& = \boxed{756}.
 
\end{align*}
 
\end{align*}
 
</cmath>
 
</cmath>
  
<math>\textbf{FINAL NOTE:}</math> In our solution, we do not use the conditio that spheres <math>A</math> and <math>B</math> are externally tangent. This condition is redundant in solving this problem.
+
<math>\textbf{FINAL NOTE:}</math> In our solution, we do not use the condition that spheres <math>A</math> and <math>B</math> are externally tangent. This condition is redundant in solving this problem.
 +
 
 +
<math>\textbf{MORE FINAL NOTE:}</math> the above note is incorrect because that condition was used at the start when claiming <math>O_AO_B=24</math>. Perhaps the note is referring to spheres <math>B</math> and <math>C</math>.
  
 
~Steven Chen (www.professorcheneeu.com)
 
~Steven Chen (www.professorcheneeu.com)
 +
 +
~anonymous (minor edits)
 +
 +
==Video Solution (Challenge 25)==
 +
 +
https://www.youtube.com/watch?v=yeuJDQ1LTlY
  
 
==Video Solution==
 
==Video Solution==
Line 168: Line 198:
 
~Steven Chen (www.professorcheneeu.com)
 
~Steven Chen (www.professorcheneeu.com)
  
==Video Solution 2 (Mathematical Dexterity)==
+
==Video Solution (Mathematical Dexterity)==
 
https://www.youtube.com/watch?v=HbBU13YiopU
 
https://www.youtube.com/watch?v=HbBU13YiopU
  

Latest revision as of 14:19, 1 February 2024

Problem

Three spheres with radii $11$, $13$, and $19$ are mutually externally tangent. A plane intersects the spheres in three congruent circles centered at $A$, $B$, and $C$, respectively, and the centers of the spheres all lie on the same side of this plane. Suppose that $AB^2 = 560$. Find $AC^2$.

Diagram

[asy] /* Made by MRENTHUSIASM */ size(300); import graph3; import solids;  currentprojection=orthographic((7,0.2,9)); triple A, B, C, OA, OB, OC; A = (0,0,0); B = (0,sqrt(560),0); C = intersectionpoints(Circle(A,sqrt(756),(0,0,1)),Circle(B,sqrt(960),(0,0,1)))[1]; OA = (0,0,4); OB = (0,sqrt(560),8); OC = (C.x,C.y,16);  draw(shift(OC)*scale3(19)*unitsphere,green,light=Viewport); draw(shift(OA)*scale3(11)*unitsphere,red,light=Viewport); draw(shift(OB)*scale3(13)*unitsphere,yellow,light=Viewport); draw(Circle(A,sqrt(105),(0,0,1))^^Circle(B,sqrt(105),(0,0,1))^^Circle(C,sqrt(105),(0,0,1))); draw((-70,-20,0)--(-70,45,0)--(20,45,0)--(20,-20,0)--cycle);  dot(OA^^OB^^OC,linewidth(4.5)); dot("$A$",A,(0,1,0),linewidth(4.5)); dot("$B$",B,(0,1,0),linewidth(4.5)); dot("$C$",C,(0,1.5,0),linewidth(4.5)); [/asy] ~MRENTHUSIASM

Solution 1

This solution refers to the Diagram section.

We let $\ell$ be the plane that passes through the spheres and $O_A$ and $O_B$ be the centers of the spheres with radii $11$ and $13$. We take a cross-section that contains $A$ and $B$, which contains these two spheres but not the third, as shown below: [asy] size(400); pair A, B, OA, OB;  B = (0,0); A = (-23.6643191,0); OB = (0,8); OA = (-23.6643191,4);  draw(circle(OB,13)); draw(circle(OA,11));  draw((-48,0)--(24,0)); label("$\ell$",(-42,0),S);  label("$A$",A,S); label("$B$",B,S); label("$O_A$",OA,N); label("$O_B$",OB,N);  draw(A--OA); draw(B--OB); draw(OA--OB); draw(OA--(0,4)); draw(OA--(-33.9112699,0)); draw(OB--(10.2469508,0)); label("$24$",midpoint(OA--OB),N); label("$\sqrt{560}$",midpoint(A--B),S); label("$11$",midpoint(OA--(-33.9112699,0)),NW); label("$13$",midpoint(OB--(10.2469508,0)),NE); label("$r$",midpoint(midpoint(A--B)--A),S); label("$r$",midpoint(midpoint(A--B)--B),S); label("$r$",midpoint(A--(-33.9112699,0)),S); label("$r$",midpoint(B--(10.2469508,0)),S); label("$x$",midpoint(midpoint(B--OB)--OB),W); label("$D$",midpoint(B--OB),E); [/asy] Because the plane cuts out congruent circles, they have the same radius and from the given information, $AB = \sqrt{560}$. Since $ABO_BO_A$ is a trapezoid, we can drop an altitude from $O_A$ to $BO_B$ to create a rectangle and triangle to use Pythagorean theorem. We know that the length of the altitude is $\sqrt{560}$ and let the distance from $O_B$ to $D$ be $x$. Then we have $x^2 = 576-560 \implies x = 4$.

We have $AO_A = BD$ because of the rectangle, so $\sqrt{11^2-r^2} = \sqrt{13^2-r^2}-4$. Squaring, we have $121-r^2 = 169-r^2 + 16 - 8 \cdot \sqrt{169-r^2}$. Subtracting, we get $8 \cdot \sqrt{169-r^2} = 64 \implies \sqrt{169-r^2} = 8 \implies 169-r^2 = 64 \implies r^2 = 105$. We also notice that since we had $\sqrt{169-r^2} = 8$ means that $BO_B = 8$ and since we know that $x = 4$, $AO_A = 4$.

We take a cross-section that contains $A$ and $C$, which contains these two spheres but not the third, as shown below: [asy] size(400); pair A, C, OA, OC, M;  C = (0,0); A = (-27.4954541697,0); OC = (0,16); OA = (-27.4954541697,4); M = midpoint(A--C);  draw(circle(OC,19)); draw(circle(OA,11));  draw((-48,0)--(24,0)); label("$\ell$",(-42,0),S);  label("$A$",A,S); label("$C$",C,S); label("$O_A$",OA,N); label("$O_C$",OC,N);  draw(A--OA); draw(C--OC); draw(OA--OC); draw(OA--(0,4)); draw(OA--(-37.8877590151,0)); draw(OC--(10.2469508,0)); label("$30$",midpoint(OA--OC),NW); label("$11$",midpoint(OA--(-37.8877590151,0)),NW); label("$19$",midpoint(OC--(10.2469508,0)),NE); label("$r$",midpoint(midpoint(M--A)--A),S); label("$r$",midpoint(midpoint(M--C)--C),S); label("$r$",midpoint(A--(-37.8877590151,0)),S); label("$r$",midpoint(C--(10.2469508,0)),S); label("$E$",(0,4),E); [/asy] We have $CO_C = \sqrt{19^2-r^2} = \sqrt{361 - 105} = \sqrt{256} = 16$. Since $AO_A = 4$, we have $EO_C = 16-4 = 12$. Using Pythagorean theorem, $O_AE = \sqrt{30^2 - 12^2} = \sqrt{900-144} = \sqrt{756}$. Therefore, $O_AE^2 = AC^2  = \boxed{756}$.

~KingRavi

Solution 2

Let the distance between the center of the sphere to the center of those circular intersections as $a,b,c$ separately.

According to the problem, we have $a^2-11^2=b^2-13^2=c^2-19^2; (11+13)^2-(b-a)^2=560.$ After solving we have $b-a=4,$ plug this back to $11^2-a^2=13^2-b^2,$ we have $a=4, b=8,$ and $c=16.$

The desired value is $(11+19)^2-(16-4)^2=\boxed{756}.$

~bluesoul

Solution 3

Denote by $r$ the radius of three congruent circles formed by the cutting plane. Denote by $O_A$, $O_B$, $O_C$ the centers of three spheres that intersect the plane to get circles centered at $A$, $B$, $C$, respectively.

Because three spheres are mutually tangent, $O_A O_B = 11 + 13 = 24$, $O_A O_C = 11 + 19 = 30$.

We have $O_A A^2 = 11^2 - r^2$, $O_B B^2 = 13^2 - r^2$, $O_C C^2 = 19^2 - r^2$.

Because $O_A A$ and $O_B B$ are perpendicular to the plane, $O_A AB O_B$ is a right trapezoid, with $\angle O_A A B = \angle O_B BA = 90^\circ$.

Hence, \begin{align*} O_B B - O_A A & = \sqrt{O_A O_B^2 - AB^2} \\ & = 4 . \hspace{1cm} (1) \end{align*}

Recall that \begin{align*} O_B B^2 - O_A A^2 & = \left( 13^2 - r^2 \right) - \left( 11^2 - r^2 \right) \\ & = 48 . \hspace{1cm} (2) \end{align*}

Hence, taking $\frac{(2)}{(1)}$, we get \[ O_B B + O_A A = 12 . \hspace{1cm} (3) \]

Solving (1) and (3), we get $O_B B = 8$ and $O_A A = 4$.

Thus, $r^2 = 11^2 - O_A A^2 = 105$.

Thus, $O_C C = \sqrt{19^2 - r^2} = 16$.

Because $O_A A$ and $O_C C$ are perpendicular to the plane, $O_A AC O_C$ is a right trapezoid, with $\angle O_A A C = \angle O_C CA = 90^\circ$.

Therefore, \begin{align*} AC^2 & = O_A O_C^2 - \left( O_C C - O_A A \right)^2 \\ & = \boxed{756}. \end{align*}

$\textbf{FINAL NOTE:}$ In our solution, we do not use the condition that spheres $A$ and $B$ are externally tangent. This condition is redundant in solving this problem.

$\textbf{MORE FINAL NOTE:}$ the above note is incorrect because that condition was used at the start when claiming $O_AO_B=24$. Perhaps the note is referring to spheres $B$ and $C$.

~Steven Chen (www.professorcheneeu.com)

~anonymous (minor edits)

Video Solution (Challenge 25)

https://www.youtube.com/watch?v=yeuJDQ1LTlY

Video Solution

https://www.youtube.com/watch?v=SqLiV2pbCpY&t=15s

~Steven Chen (www.professorcheneeu.com)

Video Solution (Mathematical Dexterity)

https://www.youtube.com/watch?v=HbBU13YiopU

See Also

2022 AIME I (ProblemsAnswer KeyResources)
Preceded by
Problem 9
Followed by
Problem 11
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
All AIME Problems and Solutions

The problems on this page are copyrighted by the Mathematical Association of America's American Mathematics Competitions. AMC logo.png