Difference between revisions of "2020 AMC 10A Problems/Problem 12"

Revision as of 12:17, 1 February 2020

Problem

Triangle $AMC$ is isoceles with $AM = AC$ . Medians $\overline{MV}$ and $\overline{CU}$ are perpendicular to each other, and $MV=CU=12$ . What is the area of $\triangle AMC?$

$\textbf{(A) } 48 \qquad \textbf{(B) } 72 \qquad \textbf{(C) } 96 \qquad \textbf{(D) } 144 \qquad \textbf{(E) } 192$

Solution 1

Since quadrilateral $UVCM$ has perpendicular diagonals, its area can be found as half of the product of the length of the diagonals. Also note that $\triangle AUV$ has $\frac 14$ the area of triangle $AMC$ by similarity, so $[UVCM]=\frac 34\cdot [AMC].$ Thus, $\frac 12 \cdot 12\cdot 12=\frac 34 \cdot [AMC]$ $72=\frac 34\cdot [AMC]$ $[AMC]=96\rightarrow \boxed{\textbf{(C)}}.$

Solution 2 (Trapezoid)

$[asy] draw((-4,0)--(4,0)--(0,12)--cycle); draw((-2,6)--(4,0)); draw((2,6)--(-4,0)); draw((-2,6)--(2,6)); label("M", (-4,0), W); label("C", (4,0), E); label("A", (0, 12), N); label("V", (2, 6), NE); label("U", (-2, 6), NW); label("P", (0, 3.6), S); [/asy]$

We know that $\triangle AUV \sim \triangle AMC$ , and since the ratios of its sides are $\frac{1}{2}$ , the ratio of of their areas is $(\frac{1}{2})^2=\frac{1}{4}$ .

If $\triangle AUV$ is $\frac{1}{4}$ the area of $\triangle AMC$ , then trapezoid $MUVC$ is $\frac{3}{4}$ the area of $\triangle AMC$ .

Let's call the intersection of $\overline{UC}$ and $\overline{MV}$ $P$ . Let $\overline{UP}=x$ . Then $\overline{PC}=12-x$ . Since $\overline{UC} \perp \overline{MV}$ , $\overline{UP}$ and $\overline{CP}$ are heights of triangles $\triangle MUV$ and $\triangle MCV$ , respectively. Both of these triangles have base $12$ .

Area of $\triangle MUV = \frac{x\cdot12}{2}=6x$

Area of $\triangle MCV = \frac{(12-x)\cdot12}{2}=72-6x$

Adding these two gives us the area of trapezoid $MUVC$ , which is $6x+(72-6x)=72$ .

This is $\frac{3}{4}$ of the triangle, so the area of the triangle is $\frac{4}{3}\cdot{72}=\boxed{\textbf{(C) } 96}$ ~quacker88, diagram by programjames1

Solution 3 (Medians)

Draw median $\overline{AB}$ . $[asy] draw((-4,0)--(4,0)--(0,12)--cycle); draw((-2,6)--(4,0)); draw((2,6)--(-4,0)); draw((0,12)--(0,0)); label("M", (-4,0), W); label("C", (4,0), E); label("A", (0, 12), N); label("V", (2, 6), NE); label("U", (-2, 6), NW); label("P", (0.5, 4), E); label("B", (0, 0), S); [/asy]$

Since we know that all medians of a triangle intersect at the incenter, we know that $\overline{AB}$ passes through point $P$ . We also know that medians of a triangle divide each other into segments of ratio $2:1$ . Knowing this, we can see that $\overline{PC}:\overline{UP}=2:1$ , and since the two segments sum to $12$ , $\overline{PC}$ and $\overline{UP}$ are $8$ and $4$ , respectively.

Finally knowing that the medians divide the triangle into $6$ sections of equal area, finding the area of $\triangle PUM$ is enough. $\overline{PC} = \overline{MP} = 8$ .

The area of $\triangle PUM = \frac{4\cdot8}{2}=16$ . Multiplying this by $6$ gives us $6\cdot16=\boxed{\textbf{(C) }96}$

~quacker88

Solution 4 (Triangles)

$[asy] draw((-4,0)--(4,0)--(0,12)--cycle); draw((-2,6)--(4,0)); draw((2,6)--(-4,0)); draw((-2,6)--(2,6)); label("M", (-4,0), W); label("C", (4,0), E); label("A", (0, 12), N); label("V", (2, 6), NE); label("U", (-2, 6), NW); label("P", (0, 3.6), S); [/asy]$ We know that $AU = UM$ , $AV = VC$ , so $UV = \frac{1}{2} MC$ .

As $\angle UPM = \angle VPC = 90$ , we can see that $\triangle UPM \cong \triangle VPC$ and $\triangle UVP \sim \triangle MPC$ with a side ratio of $1 : 2$ .

So $UP = VP = 4$ , $MP = PC = 8$ .

With that, we can see that $S\triangle UPM = 16$ , and the area of trapezoid $MUVC$ is 72.

As said in solution 1, $S\triangle AMC = 72 / \frac{3}{4} = \boxed{\textbf{(C) } 96}$ .

-QuadraticFunctions, solution 1 by ???

Solution 5 (Medians, Height, Pythagorean Theorem, Lots of symmetry, A little extra work)

[asy] draw((-4,0)--(4,0)--(0,12)--cycle); draw((-2,6)--(4,0)); draw((2,6)--(-4,0)); draw((0,12)--(0,0)); draw((-2, 6)--(2, 6)); label("K", (0, 6), NE); label("M", (-4,0), W); label("C", (4,0), E); label("A", (0, 12), N); label("V", (2, 6), NE); label("U", (-2, 6), NW); label("P", (0.5, 4), E); label("B", (0, 0), S); [/asy]

It is well known that medians divide each other into segments of $2:1$ ratio. From this, we have $PC=MP=8$ and $UP=UV=4$ . From right triangle $\triangle{MPC}$ , $MC^2=MP^2+MC^2=8^2+8^2=128$ , which implies $MC=\sqrt{128}=8\sqrt{2}$ . Then the area of $\triangle{AMC}$ is $\dfrac{8\sqrt{2} \cdot AB}{2}$ , so our goal is to find $AB$ .

Note that $AB=AP+BP$ . Since $\triangle{AMC}$ is isosceles, by symmetry $MB=MC$ , because $AB$ is the altitude. Knowing this, $BP$ is the median to hypotenuse $MC$ of triangle $\triangle{MPC}$ , which means $2BP=MC$ . Since $MC=8\sqrt{2}$ , $BP=4\sqrt{2}$ .

Now we find $AP$ . Note $AP=AK+KP$ . From right triangle $\triangle{AVP}$ , we have $UV=4\sqrt{2}$ by the Pythagorean Theorem. By symmetry, $PK$ is the median to hypotenuse $UV$ , which means $2PK=UV$ . This trivially means $PK=2\sqrt{2}$ .

Notice quadrilateral $AUPV$ is a kite, which means $\triangle{AKU}$ is right(the diagonals are perpendicular). By the Pythagorean Theorem, $AK^2=AU^2-UK^2$ . Since $CU$ is a median, $AU=UM$ . From right triangle $\triangle{UPM}$ , $UM^2=UP^2+MP^2=4^2+8^2=80$ , which means $UM=4\sqrt{5}$ , and thus $AU=4\sqrt{5}$ . From our previous equation $AK^2=AU^2-UK^2$ , we thus have $AK^2=80-UK^2=80-\left(\dfrac{UV}{2}\right)=80-8=72$ , so $AK=6\sqrt{2}$ . We also know $PK=2\sqrt{2}$ , so $AP=AK+PK=8\sqrt{2}$ .

Recall that $AB=AP+BP=8\sqrt{2}+4\sqrt{2}=12\sqrt{2}$ . By the area formula, $[ABC]=\dfrac{AB \cdot MC}{2}=\dfrac{8\sqrt{2} \cdot 12\sqrt{2}}{2}=\dfrac{96 \cdot 2}{2}=\boxed{96}$ .

Video Solution

https://youtu.be/ZGwAasE32Y4

~IceMatrix

@@ Line 90: / Line 90: @@
 ==Solution 5 (Medians, Height, Pythagorean Theorem, Lots of symmetry, A little extra work)==
-[asy] draw((-4,0)--(4,0)--(0,12)--cycle); draw((-2,6)--(4,0)); draw((2,6)--(-4,0)); draw((0,12)--(0,0)); draw((-2, 6)--(2, 6)) label("K", (0, 6), NE); label("M", (-4,0), W); label("C", (4,0), E); label("A", (0, 12), N); label("V", (2, 6), NE); label("U", (-2, 6), NW); label("P", (0.5, 4), E); label("B", (0, 0), S); [/asy]
+[asy] draw((-4,0)--(4,0)--(0,12)--cycle); draw((-2,6)--(4,0)); draw((2,6)--(-4,0)); draw((0,12)--(0,0)); draw((-2, 6)--(2, 6)); label("K", (0, 6), NE); label("M", (-4,0), W); label("C", (4,0), E); label("A", (0, 12), N); label("V", (2, 6), NE); label("U", (-2, 6), NW); label("P", (0.5, 4), E); label("B", (0, 0), S); [/asy]
 It is well known that medians divide each other into segments of <math>2:1</math> ratio. From this, we have <math>PC=MP=8</math> and <math>UP=UV=4</math>. From right triangle <math>\triangle{MPC}</math>, <math>MC^2=MP^2+MC^2=8^2+8^2=128</math>, which implies <math>MC=\sqrt{128}=8\sqrt{2}</math>. Then the area of <math>\triangle{AMC}</math> is <math>\dfrac{8\sqrt{2} \cdot AB}{2}</math>, so our goal is to find <math>AB</math>.
@@ Line 98: / Line 98: @@
 Now we find <math>AP</math>. Note <math>AP=AK+KP</math>. From right triangle <math>\triangle{AVP}</math>, we have <math>UV=4\sqrt{2}</math> by the Pythagorean Theorem. By symmetry, <math>PK</math> is the median to hypotenuse <math>UV</math>, which means <math>2PK=UV</math>. This trivially means <math>PK=2\sqrt{2}</math>.
-Notice quadrilateral <math>AUPV</math> is a kite, which means <math>\triangle{AKU}</math> is right(the diagonals are perpendicular). By the Pythagorean Theorem, <math>AK^2=AU^2-UK^2</math>. Since <math>CU</math> is a median, <math>AU=UM</math>. From right triangle <math>\triangle{UPM}</math>, <math>UM^2=UP^2+MP^2=4^2+8^2=80</math>, which means <math>UM=4\sqrt{5}</math>, and thus <math>AU=4\sqrt{5}</math>. From our previous equation <math>AK^2=AU^2-UK^2</math>, we thus have <cmath>AK^2=80-UK^2=80-\left(\dfrac{UV}{2}]\right)=80-8=72</cmath>, so <math>AK=6\sqrt{2}</math>. We also know <math>PK=2\sqrt{2}</math>, so <math>AP=AK+PK=8\sqrt{2}</math>.
+Notice quadrilateral <math>AUPV</math> is a kite, which means <math>\triangle{AKU}</math> is right(the diagonals are perpendicular). By the Pythagorean Theorem, <math>AK^2=AU^2-UK^2</math>. Since <math>CU</math> is a median, <math>AU=UM</math>. From right triangle <math>\triangle{UPM}</math>, <math>UM^2=UP^2+MP^2=4^2+8^2=80</math>, which means <math>UM=4\sqrt{5}</math>, and thus <math>AU=4\sqrt{5}</math>. From our previous equation <math>AK^2=AU^2-UK^2</math>, we thus have <cmath>AK^2=80-UK^2=80-\left(\dfrac{UV}{2}\right)=80-8=72</cmath>, so <math>AK=6\sqrt{2}</math>. We also know <math>PK=2\sqrt{2}</math>, so <math>AP=AK+PK=8\sqrt{2}</math>.
 Recall that <math>AB=AP+BP=8\sqrt{2}+4\sqrt{2}=12\sqrt{2}</math>. By the area formula, <cmath>[ABC]=\dfrac{AB \cdot MC}{2}=\dfrac{8\sqrt{2} \cdot 12\sqrt{2}}{2}=\dfrac{96 \cdot 2}{2}=\boxed{96}</cmath>.

2020 AMC 10A (Problems • Answer Key • Resources)
Preceded by Problem 11	Followed by Problem 13
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