Difference between revisions of "1982 USAMO Problems/Problem 5"

Revision as of 15:02, 11 July 2018

Problem

$A,B$ , and $C$ are three interior points of a sphere $S$ such that $AB$ and $AC$ are perpendicular to the diameter of $S$ through $A$ , and so that two spheres can be constructed through $A$ , $B$ , and $C$ which are both tangent to $S$ . Prove that the sum of their radii is equal to the radius of $S$ .

Solution

Let the two tangent spheres be $S_1$ and $S_2$ , and let $O, O_1, O_2$ and $R, R_1, R_2$ be the origins and radii of $S, S_1, S_2$ respectively. Then $AO$ stands normal to the plane $P$ through $\Delta ABC$ . Because both spheres go through $A$ , $B$ , and $C$ , the line $O_1 O_2$ also stands normal to $P$ , meaning $AO$ and $O_1 O_2$ are both coplanar and parallel. Therefore the problem can be flattened to the plane $P'$ through $A$ , $O$ , $O_1$ and $O_2$ .

Let $X, Y, Z, M, N$ be points on $P'$ such that $X = S \cap S_1, \quad Y = S_1 \cap S_2 \neq A, \quad Z = S \cap S_2, \quad M = O_1 Y \cap AO, \quad N = O_2 Y \cap AO$

Let $J$ be the three circles radical center, meaning $JX$ and $JZ$ are tangent segments to $S$ and $J \in AY$ .

Because $Y \in P \iff \angle NAY = \angle YAM = 90 ^{\circ},$ we have that $\overline{YN}$ and $\overline{YM}$ are diameters.

This means that $\angle OZN = \angle ZNY = \angle JZY$ and $\angle MXO = \angle YMX= \angle YXJ$ .

And because $\angle ZNO = 180^{\circ} - \angle AYZ = \angle ZYJ$ and $\angle OMX = 180^{\circ} -\angle XYA = \angle JYX,$ we have that $\Delta JZY \sim \Delta OZN$ and $\Delta JYX \sim \Delta OMX$ .

We then conclude that $\overline{OM} = \overline{OX} \enspace \frac {\overline{JY} }{ \overline{JX}} = \overline{OZ} \enspace \frac {\overline{JY} }{ \overline{JZ}} = \overline{ON}$

Let $a \top b$ denote line $a$ bisecting line segment $b$ .

Since $O_1 O_2 || MN$ it follows that $OY \, \top \, \overline{MN} \Rightarrow OY \, \top \, \overline{O_1 O_2}$ . Similarly we have that $O_1 O_2 \, \top \, \overline{YM} \Rightarrow O_1 O_2 \, \top \, \overline{OY}$ .

And so $O_1 O O_2 Y$ is a parallelogram because $\overline{OY}$ and $\overline{O_1 O_2}$ bisect each other, meaning $R = \overline{OZ} = \overline{O O_2} + \overline{O_2 Z} = \overline{O_1 Y}+ R_2 = R_1 + R_2$

$Quod \enspace Erat \enspace Demonstrandum$

@@ Line 17: / Line 17: @@
 And because <math>\angle ZNO = 180^{\circ} - \angle AYZ = \angle ZYJ</math> and <math>\angle OMX = 180^{\circ} -\angle XYA = \angle JYX,</math> we have that <math>\Delta JZY \sim \Delta OZN</math> and <math>\Delta JYX \sim \Delta OMX</math>.
-We then conclude that <math>\overline{OM} = \overline{OX} \enspace \frac {\overline{JY} }{ \overline{JX}}  = \overline{OZ} \enspace \frac {\overline{JY} }{ \overline{JX}}  = \overline{ON}</math>
+We then conclude that <math>\overline{OM} = \overline{OX} \enspace \frac {\overline{JY} }{ \overline{JX}}  = \overline{OZ} \enspace \frac {\overline{JY} }{ \overline{JZ}}  = \overline{ON}</math>
@@ Line 29: / Line 29: @@
 <math>Quod \enspace Erat \enspace Demonstrandum</math>
 == See Also ==

1982 USAMO (Problems • Resources)
Preceded by Problem 4	Followed by Last Question
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Difference between revisions of "1982 USAMO Problems/Problem 5"

Revision as of 15:02, 11 July 2018

Problem

Solution

See Also