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Difference between revisions of "2018 AIME I Problems/Problem 13"

(Solution 2 (A more elegant, but lengthy, approach))
(Solution 2 (A more elegant, but lengthy, approach))
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==Solution 2 (A more elegant, but lengthy, approach)==
 
==Solution 2 (A more elegant, but lengthy, approach)==
  
First, instead of using angles to find <math>[AI_1I_2]</math>, let's try to find the area of other, more simpler figures, and subtract that from <math>[ABC]</math>. However, to do this, we need to be able to figure out the length of the inradii, and so, we need to find <math>AX</math>. To minimize <math>[AI_1I_2]</math>, intuitively, we should try to minimize the length of <math>AX</math>, since, after using the <math>rs=A</math> formula for the area of a triangle, we'll be able to minimize the inradii lengths, and thus, eventually minimize the area of <math>[AI_1I_2]</math> (I did not come up with a solid proof to back this intuition, if any does, don't hesitate to add a note at the bottom).
+
First, instead of using angles to find <math>[AI_1I_2]</math>, let's try to find the area of other, simpler figures, and subtract that from <math>[ABC]</math>. However, to do this, we need to be able to figure out the length of the inradii, and so, we need to find <math>AX</math>. To minimize <math>[AI_1I_2]</math>, intuitively, we should try to minimize the length of <math>AX</math>, since, after using the <math>rs=A</math> formula for the area of a triangle, we'll be able to minimize the inradii lengths, and thus, eventually minimize the area of <math>[AI_1I_2]</math> (Proof needed here).
  
To minimize <math>AX</math>, let's use Stewart's Theorem. Let <math>AX=d</math>, <math>BX=s</math>, and <math>CX=32-s</math>. After an application of Stewart's Theorem, we will get that <cmath>d=\sqrt{s^2-24s+900}</cmath> To minimize this quadratic, we need to let <math>s=12</math> whereby we conclude that <math>d=6\sqrt{21}</math>.  
+
To minimize <math>AX</math>, use Stewart's Theorem. Let <math>AX=d</math>, <math>BX=s</math>, and <math>CX=32-s</math>. After an application of Stewart's Theorem, we will get that <cmath>d=\sqrt{s^2-24s+900}</cmath> To minimize this quadratic, we need to let <math>s=12</math> whereby we conclude that <math>d=6\sqrt{21}</math>.  
  
From here, draw perpendiculars down from <math>I_1</math> and <math>I_2</math> to <math>AB</math> and <math>AC</math> respectively, and label the foot of these perpendiculars <math>D</math> and <math>E</math> respectively. After, draw the inradii from <math>I_1</math> to <math>BX</math>, and from <math>I_2</math> to <math>CX</math>,  and draw in <math>I_1I_2</math>. Label the foot of the inradii to <math>BX</math> and <math>CX</math>, <math>F</math> and <math>G</math>, respectively. From here, we see that to find <math>[AI_1I_2]</math>, we need to find <math>[ABC]</math>, and subtract off the sum of <math>[DBCEI_2I_1]</math>, <math>[ADI_1]</math>, and <math>[AEI_2]</math>.  
+
From here, draw perpendiculars down from <math>I_1</math> and <math>I_2</math> to <math>AB</math> and <math>AC</math> respectively, and label the foot of these perpendiculars <math>D</math> and <math>E</math> respectively. After, draw the inradii from <math>I_1</math> to <math>BX</math>, and from <math>I_2</math> to <math>CX</math>,  and draw in <math>I_1I_2</math>.  
  
<math>[DBCEI_2I_1]</math> can be found by finding the area of two quadrilaterals (<math>[DBFI_1]</math>+<math>[ECGI_2]</math>) as well as the area of a trapezoid (<math>[FGI_2I_1]</math>). If we let the inradius of <math>ABX</math> be <math>r_1</math> and if we let the inradius of <math>ACX</math> be <math>r_2</math>, we'll find, after an application of basic geometry and careful calculations on paper, that <math>[DBCEI_2I_1]=13r_1+19r_2</math>.  
+
Label the foot of the inradii to <math>BX</math> and <math>CX</math>, <math>F</math> and <math>G</math>, respectively. From here, we see that to find <math>[AI_1I_2]</math>, we need to find <math>[ABC]</math>, and subtract off the sum of <math>[DBCEI_2I_1], [ADI_1],</math> and <math>[AEI_2]</math>.  
  
The area of two triangles can be found in a similar fashion, however, we must use <math>XYZ</math> substitution to solve for <math>AD</math> as well as <math>AE</math>. After doing this, we'll get a similar sum in terms of <math>r_1</math> and <math>r_2</math> for the area of those two triangles (I'm not very good at LaTeX, so I can't typeset the area, but the area of the two triangles is equal to (9+3sqrt(21)(r_1)/2 + (7+3sqrt(21)(r_2)/2).
+
<math>[DBCEI_2I_1]</math> can be found by finding the area of two quadrilaterals <math>[DBFI_1]+[ECGI_2]</math> as well as the area of a trapezoid <math>[FGI_2I_1]</math>. If we let the inradius of <math>ABX</math> be <math>r_1</math> and if we let the inradius of <math>ACX</math> be <math>r_2</math>, we'll find, after an application of basic geometry and careful calculations on paper, that <math>[DBCEI_2I_1]=13r_1+19r_2</math>.  
  
Now we're set. Summing up the area of the Hexagon and the two triangles and simplifying, we get that the formula for <math>[AI_1I_2]</math> is just [ABC]-(35+3sqrt(21)(r_1)/2 -(45+3sqrt(21)(r_2)/2.  
+
The area of two triangles can be found in a similar fashion, however, we must use <math>XYZ</math> substitution to solve for <math>AD</math> as well as <math>AE</math>. After doing this, we'll get a similar sum in terms of <math>r_1</math> and <math>r_2</math> for the area of those two triangles which is equal to <math>\frac{(9+3\sqrt{21})(r_1)}{2} + \frac{(7+3\sqrt{21})(r_2)}{2}</math>.
  
Using Heron's formula, <math>[ABC]=96sqrt{21}</math>. Solving for <math>r_1</math> and <math>r_2</math> using Heron's in <math>ABX</math> and <math>ACX</math>, we get that <math>r_1=3sqrt{21}-9</math> and <math>r_2=3sqrt{21}-7</math>. From here, we just have to plug into our above equation and solve. Doing so gets us that the minimum area of <math>AI_1I_2=126</math>.
+
Now we're set. Summing up the area of the Hexagon and the two triangles and simplifying, we get that the formula for <math>[AI_1I_2]</math> is just <math>[ABC]-\left(\frac{(35+3\sqrt{21})(r_1)}{2}+\frac{(45+3r_2\sqrt{21})(r_2)}{2}\right)</math>.  
  
-Mathislife52
+
Using Heron's formula, <math>[ABC]=96\sqrt{21}</math>. Solving for <math>r_1</math> and <math>r_2</math> using Heron's in <math>ABX</math> and <math>ACX</math>, we get that <math>r_1=3\sqrt{21}-9</math> and <math>r_2=3\sqrt{21}-7</math>. From here, we just have to plug into our above equation and solve. Doing so gets us that the minimum area of <math>AI_1I_2=\boxed{126}</math>.
 +
 
 +
-Mathislife52 ~edited by phoenixfire
  
 
==See Also==
 
==See Also==

Revision as of 03:08, 9 November 2020

Problem

Let $\triangle ABC$ have side lengths $AB=30$, $BC=32$, and $AC=34$. Point $X$ lies in the interior of $\overline{BC}$, and points $I_1$ and $I_2$ are the incenters of $\triangle ABX$ and $\triangle ACX$, respectively. Find the minimum possible area of $\triangle AI_1I_2$ as $X$ varies along $\overline{BC}$.

Solution 1 (Official MAA)

First note that \[\angle I_1AI_2 = \angle I_1AX + \angle XAI_2 = \frac{\angle BAX}2 + \frac{\angle CAX}2 = \frac{\angle A}2\] is a constant not depending on $X$, so by $[AI_1I_2] = \tfrac12(AI_1)(AI_2)\sin\angle I_1AI_2$ it suffices to minimize $(AI_1)(AI_2)$. Let $a = BC$, $b = AC$, $c = AB$, and $\alpha = \angle AXB$. Remark that \[\angle AI_1B = 180^\circ - (\angle I_1AB + \angle I_1BA) = 180^\circ - \tfrac12(180^\circ - \alpha) = 90^\circ + \tfrac\alpha 2.\] Applying the Law of Sines to $\triangle ABI_1$ gives \[\frac{AI_1}{AB} = \frac{\sin\angle ABI_1}{\sin\angle AI_1B}\qquad\Rightarrow\qquad AI_1 = \frac{c\sin\frac B2}{\cos\frac\alpha 2}.\] Analogously one can derive $AI_2 = \tfrac{b\sin\frac C2}{\sin\frac\alpha 2}$, and so \[[AI_1I_2] = \frac{bc\sin\frac A2 \sin\frac B2\sin\frac C2}{2\cos\frac\alpha 2\sin\frac\alpha 2} = \frac{bc\sin\frac A2 \sin\frac B2\sin\frac C2}{\sin\alpha}\geq bc\sin\frac A2 \sin\frac B2\sin\frac C2,\] with equality when $\alpha = 90^\circ$, that is, when $X$ is the foot of the perpendicular from $A$ to $\overline{BC}$. In this case the desired area is $bc\sin\tfrac A2\sin\tfrac B2\sin\tfrac C2$. To make this feasible to compute, note that \[\sin\frac A2=\sqrt{\frac{1-\cos A}2}=\sqrt{\frac{1-\frac{b^2+c^2-a^2}{2bc}}2} = \sqrt{\dfrac{(a-b+c)(a+b-c)}{4bc}}.\] Applying similar logic to $\sin \tfrac B2$ and $\sin\tfrac C2$ and simplifying yields a final answer of \begin{align*}bc\sin\frac A2\sin\frac B2\sin\frac C2&=bc\cdot\dfrac{(a-b+c)(b-c+a)(c-a+b)}{8abc}\\&=\dfrac{(30-32+34)(32-34+30)(34-30+32)}{8\cdot 32}=\boxed{126}.\end{align*}


Solution 2 (A more elegant, but lengthy, approach)

First, instead of using angles to find $[AI_1I_2]$, let's try to find the area of other, simpler figures, and subtract that from $[ABC]$. However, to do this, we need to be able to figure out the length of the inradii, and so, we need to find $AX$. To minimize $[AI_1I_2]$, intuitively, we should try to minimize the length of $AX$, since, after using the $rs=A$ formula for the area of a triangle, we'll be able to minimize the inradii lengths, and thus, eventually minimize the area of $[AI_1I_2]$ (Proof needed here).

To minimize $AX$, use Stewart's Theorem. Let $AX=d$, $BX=s$, and $CX=32-s$. After an application of Stewart's Theorem, we will get that \[d=\sqrt{s^2-24s+900}\] To minimize this quadratic, we need to let $s=12$ whereby we conclude that $d=6\sqrt{21}$.

From here, draw perpendiculars down from $I_1$ and $I_2$ to $AB$ and $AC$ respectively, and label the foot of these perpendiculars $D$ and $E$ respectively. After, draw the inradii from $I_1$ to $BX$, and from $I_2$ to $CX$, and draw in $I_1I_2$.

Label the foot of the inradii to $BX$ and $CX$, $F$ and $G$, respectively. From here, we see that to find $[AI_1I_2]$, we need to find $[ABC]$, and subtract off the sum of $[DBCEI_2I_1], [ADI_1],$ and $[AEI_2]$.

$[DBCEI_2I_1]$ can be found by finding the area of two quadrilaterals $[DBFI_1]+[ECGI_2]$ as well as the area of a trapezoid $[FGI_2I_1]$. If we let the inradius of $ABX$ be $r_1$ and if we let the inradius of $ACX$ be $r_2$, we'll find, after an application of basic geometry and careful calculations on paper, that $[DBCEI_2I_1]=13r_1+19r_2$.

The area of two triangles can be found in a similar fashion, however, we must use $XYZ$ substitution to solve for $AD$ as well as $AE$. After doing this, we'll get a similar sum in terms of $r_1$ and $r_2$ for the area of those two triangles which is equal to $\frac{(9+3\sqrt{21})(r_1)}{2} + \frac{(7+3\sqrt{21})(r_2)}{2}$.

Now we're set. Summing up the area of the Hexagon and the two triangles and simplifying, we get that the formula for $[AI_1I_2]$ is just $[ABC]-\left(\frac{(35+3\sqrt{21})(r_1)}{2}+\frac{(45+3r_2\sqrt{21})(r_2)}{2}\right)$.

Using Heron's formula, $[ABC]=96\sqrt{21}$. Solving for $r_1$ and $r_2$ using Heron's in $ABX$ and $ACX$, we get that $r_1=3\sqrt{21}-9$ and $r_2=3\sqrt{21}-7$. From here, we just have to plug into our above equation and solve. Doing so gets us that the minimum area of $AI_1I_2=\boxed{126}$.

-Mathislife52 ~edited by phoenixfire

See Also

2018 AIME I (ProblemsAnswer KeyResources)
Preceded by
Problem 12 		Followed by
Problem 14
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
All AIME Problems and Solutions

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