Difference between revisions of "2021 AIME I Problems/Problem 8"
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==Problem== | ==Problem== | ||
− | Find the number of integers <math>c</math> such that the equation<cmath>\left||20|x|-x^2|-c\right|=21</cmath>has <math>12</math> distinct real solutions. | + | Find the number of integers <math>c</math> such that the equation <cmath>\left||20|x|-x^2|-c\right|=21</cmath>has <math>12</math> distinct real solutions. |
− | ==Solution 1== | + | ==Solution 1 (Piecewise Function: Analysis and Graph)== |
+ | We take cases for the outermost absolute value, then rearrange: <cmath>\left|20|x|-x^2\right|=c\pm21.</cmath> | ||
+ | Let <math>f(x)=\left|20|x|-x^2\right|.</math> We rewrite <math>f(x)</math> as a piecewise function without using absolute values: | ||
+ | <cmath>f(x) = \begin{cases} | ||
+ | \left|-20x-x^2\right| & \mathrm{if} \ x \le 0 | ||
+ | \begin{cases} | ||
+ | 20x+x^2 & \mathrm{if} \ x\le-20 \\ | ||
+ | -20x-x^2 & \mathrm{if} \ -20<x\leq0 | ||
+ | \end{cases} \\ | ||
+ | \left|20x-x^2\right| & \mathrm{if} \ x > 0 | ||
+ | \begin{cases} | ||
+ | 20x-x^2 & \mathrm{if} \ 0<x\leq20 \\ | ||
+ | -20x+x^2 & \mathrm{if} \ x>20 | ||
+ | \end{cases} | ||
+ | \end{cases}.</cmath> | ||
+ | We graph <math>y=f(x)</math> with all extremum points labeled, as shown below. The fact that <math>f(x)</math> is an even function (<math>f(x)=f(-x)</math> holds for all real numbers <math>x,</math> so the graph of <math>y=f(x)</math> is symmetric about the <math>y</math>-axis) should facilitate the process of graphing. | ||
+ | <asy> | ||
+ | /* Made by MRENTHUSIASM */ | ||
+ | size(1200,300); | ||
+ | |||
+ | real xMin = -65; | ||
+ | real xMax = 65; | ||
+ | real yMin = -50; | ||
+ | real yMax = 125; | ||
+ | |||
+ | draw((xMin,0)--(xMax,0),black+linewidth(1.5),EndArrow(5)); | ||
+ | draw((0,yMin)--(0,yMax),black+linewidth(1.5),EndArrow(5)); | ||
+ | label("$x$",(xMax,0),(2,0)); | ||
+ | label("$y$",(0,yMax),(0,2)); | ||
− | + | real f(real x) { return abs(20*abs(x)-x^2); } | |
+ | real g(real x) { return 21; } | ||
+ | real h(real x) { return -21; } | ||
+ | draw(graph(f,-25,25),red,"$y=\left|20|x|-x^2\right|$"); | ||
+ | draw(graph(g,-65,65),blue,"$y=\pm21$"); | ||
+ | draw(graph(h,-65,65),blue); | ||
+ | |||
+ | pair A[]; | ||
+ | A[0] = (-20,0); | ||
+ | A[1] = (-10,100); | ||
+ | A[2] = (0,0); | ||
+ | A[3] = (10,100); | ||
+ | A[4] = (20,0); | ||
+ | |||
+ | for(int i = 0; i <= 4; ++i) { | ||
+ | dot(A[i],red+linewidth(4.5)); | ||
+ | } | ||
+ | |||
+ | label("$(-20,0)$",A[0],(-1.5,-1.5),red,UnFill); | ||
+ | label("$(-10,100)$",A[1],(-1.5,1.5),red); | ||
+ | label("$(0,0)$",A[2],(0,-1.5),red,UnFill); | ||
+ | label("$(10,100)$",A[3],(1.5,1.5),red); | ||
+ | label("$(20,0)$",A[4],(1.5,-1.5),red,UnFill); | ||
+ | |||
+ | add(legend(),point(E),40E,UnFill); | ||
+ | </asy> | ||
+ | Since <math>f(x)=c\pm21</math> has <math>12</math> distinct real solutions, it is clear that each case has <math>6</math> distinct real solutions geometrically. We shift the graphs of <math>y=\pm21</math> up <math>c</math> units, where <math>c\geq0:</math> | ||
+ | |||
+ | * For <math>f(x)=c+21</math> to have <math>6</math> distinct real solutions, we need <math>0\leq c<79.</math> | ||
− | + | * For <math>f(x)=c-21</math> to have <math>6</math> distinct real solutions, we need <math>21<c<121.</math> | |
− | + | Taking the intersection of these two cases gives <math>21<c<79,</math> from which there are <math>79-21-1=\boxed{057}</math> such integers <math>c.</math> | |
− | |||
− | |||
− | |||
− | + | ~MRENTHUSIASM | |
− | |||
− | ==Solution 2 ( | + | ==Solution 2 (Graphing)== |
− | Graph <math>y=|20|x|-x^2|</math>. Notice that we want this to be equal to <math>c-21</math> and <math>c+21</math>. | + | Graph <math>y=|20|x|-x^2|</math> (If you are having trouble, look at the description in the next two lines and/or the diagram in Solution 1). Notice that we want this to be equal to <math>c-21</math> and <math>c+21</math>. |
We see that from left to right, the graph first dips from very positive to <math>0</math> at <math>x=-20</math>, then rebounds up to <math>100</math> at <math>x=-10</math>, then falls back down to <math>0</math> at <math>x=0</math>. | We see that from left to right, the graph first dips from very positive to <math>0</math> at <math>x=-20</math>, then rebounds up to <math>100</math> at <math>x=-10</math>, then falls back down to <math>0</math> at <math>x=0</math>. | ||
Line 40: | Line 92: | ||
It is easy to verify that all of these choices of <math>c</math> produce <math>12</math> distinct solutions (none overlap), so our answer is <math>\boxed{057}</math>. | It is easy to verify that all of these choices of <math>c</math> produce <math>12</math> distinct solutions (none overlap), so our answer is <math>\boxed{057}</math>. | ||
− | ==Solution 3 ( | + | ==Solution 3 (Graphing)== |
− | + | ||
− | + | Let <math>y = |x|.</math> Then the equation becomes <math>\left|\left|20y-y^2\right|-c\right| = 21</math>, or <math>\left|y^2-20y\right| = c \pm 21</math>. Note that since <math>y = |x|</math>, <math>y</math> is nonnegative, so we only care about nonnegative solutions in <math>y</math>. Notice that each positive solution in <math>y</math> gives two solutions in <math>x</math> (<math>x = \pm y</math>), whereas if <math>y = 0</math> is a solution, this only gives one solution in <math>x</math>, <math>x = 0</math>. Since the total number of solutions in <math>x</math> is even, <math>y = 0</math> must not be a solution. Hence, we require that <math>\left|y^2-20y\right| = c \pm 21</math> has exactly <math>6</math> positive solutions and is not solved by <math>y = 0.</math> | |
− | < | + | |
− | + | If <math>c < 21</math>, then <math>c - 21</math> is negative, and therefore cannot be the absolute value of <math>y^2 - 20y</math>. This means the equation's only solutions are in <math>\left|y^2-20y\right| = c + 21</math>. There is no way for this equation to have <math>6</math> solutions, since the quadratic <math>y^2-20y</math> can only take on each of the two values <math>\pm(c + 21)</math> at most twice, yielding at most <math>4</math> solutions. Hence, <math>c \ge 21</math>. <math>c</math> also can't equal <math>21</math>, since this would mean <math>y = 0</math> would solve the equation. Hence, <math>c > 21.</math> | |
− | \ | + | |
− | + | At this point, the equation <math>y^2-20y = c \pm 21</math> will always have exactly <math>2</math> positive solutions, since <math>y^2-20y</math> takes on each positive value exactly once when <math>y</math> is restricted to positive values (graph it to see this), and <math>c \pm 21</math> are both positive. Therefore, we just need <math>y^2-20y = -(c \pm 21)</math> to have the remaining <math>4</math> solutions exactly. This means the horizontal lines at <math>-(c \pm 21)</math> each intersect the parabola <math>y^2 - 20y</math> in two places. This occurs when the two lines are above the parabola's vertex <math>(10,-100)</math>. Hence we have | |
− | + | <cmath>\begin{align*} | |
− | + | -(c + 21) &> -100 \\ | |
− | \left| | + | c + 21 &< 100 \\ |
− | \ | + | c &< 79. |
− | + | \end{align*}</cmath> | |
− | + | Hence, the integers <math>c</math> satisfying the conditions are those satisfying <math>21 < c < 79.</math> There are <math>\boxed{057}</math> such integers. | |
− | \ | + | |
− | \ | + | Note: Be careful of counting at the end, you may mess up and get <math>59</math>. |
+ | |||
+ | ==Solution 4 (Algebra)== | ||
+ | |||
+ | Removing the absolute value bars from the equation successively, we get | ||
+ | <cmath>\begin{align*} | ||
+ | \left|\left|20|x|-x^2\right|-c\right|&=21 \\ | ||
+ | \left|20|x|-x^2\right|&= c \pm21 \\ | ||
+ | 20|x|-x^2 &= \pm c \pm 21 \\ | ||
+ | x^2 \pm 20x \pm c \pm21 &= 0. | ||
+ | \end{align*}</cmath> | ||
+ | The discriminant of this equation is | ||
+ | <cmath>\sqrt{400-4(\pm c \pm 21)}.</cmath> | ||
+ | Equating the discriminant to <math>0</math>, we see that there will be two distinct solutions to each of the possible quadratics above only in the interval <math>-79 < c < 79</math>. However, the number of zeros the equation <math>ax^2+b|x|+k</math> has is determined by where <math>ax^2+bx+k</math> and <math>ax^2-bx+k</math> intersect, namely at <math>(0,k)</math>. When <math>k<0</math>, <math>a>0</math>, <math>ax^2+b|x|+k</math> will have only <math>2</math> solutions, and when <math>k>0</math>, <math>a>0</math>, then there will be <math>4</math> real solutions, if they exist at all. | ||
+ | In order to have <math>12</math> solutions here, we thus need to ensure <math>-c+21<0</math>, so that exactly <math>2</math> out of the <math>4</math> possible equations of the form <math>ax^2+b|x|+k</math> given above have y-intercepts below <math>0</math> and only <math>2</math> real solutions, while the remaining <math>2</math> equations have <math>4</math> solutions. This occurs when <math>c>21</math>, so our final bounds are <math>21<c<79</math>, giving us <math>\boxed{057}</math> valid values of <math>c</math>. | ||
+ | |||
+ | ==Remark== | ||
+ | The graphs of <math>F(x)=\left||20|x|-x^2|-c\right|</math> and <math>G(x)=21</math> are shown here in Desmos: https://www.desmos.com/calculator/i6l98lxwpp | ||
− | < | + | Move the slider around for <math>21<c<79</math> to observe how they intersect for <math>12</math> times. |
~MRENTHUSIASM | ~MRENTHUSIASM | ||
− | ==See | + | ==Video Solution== |
+ | https://youtu.be/6k-uR71_jg0 | ||
+ | ~mathproblemsolvingskills.com | ||
+ | |||
+ | ==See Also== | ||
{{AIME box|year=2021|n=I|num-b=7|num-a=9}} | {{AIME box|year=2021|n=I|num-b=7|num-a=9}} | ||
[[Category:Intermediate Algebra Problems]] | [[Category:Intermediate Algebra Problems]] | ||
{{MAA Notice}} | {{MAA Notice}} |
Latest revision as of 00:27, 24 December 2022
Contents
Problem
Find the number of integers such that the equation has distinct real solutions.
Solution 1 (Piecewise Function: Analysis and Graph)
We take cases for the outermost absolute value, then rearrange: Let We rewrite as a piecewise function without using absolute values: We graph with all extremum points labeled, as shown below. The fact that is an even function ( holds for all real numbers so the graph of is symmetric about the -axis) should facilitate the process of graphing. Since has distinct real solutions, it is clear that each case has distinct real solutions geometrically. We shift the graphs of up units, where
- For to have distinct real solutions, we need
- For to have distinct real solutions, we need
Taking the intersection of these two cases gives from which there are such integers
~MRENTHUSIASM
Solution 2 (Graphing)
Graph (If you are having trouble, look at the description in the next two lines and/or the diagram in Solution 1). Notice that we want this to be equal to and .
We see that from left to right, the graph first dips from very positive to at , then rebounds up to at , then falls back down to at .
The positive are symmetric, so the graph re-ascends to at , falls back to at , and rises to arbitrarily large values afterwards.
Now we analyze the (varied by ) values. At , we will have no solutions, as the line will have no intersections with our graph.
At , we will have exactly solutions for the three zeroes.
At for any strictly between and , we will have exactly solutions.
At , we will have solutions, because local maxima are reached at .
At , we will have exactly solutions.
To get distinct solutions for , both and must produce solutions.
Thus and , so is required.
It is easy to verify that all of these choices of produce distinct solutions (none overlap), so our answer is .
Solution 3 (Graphing)
Let Then the equation becomes , or . Note that since , is nonnegative, so we only care about nonnegative solutions in . Notice that each positive solution in gives two solutions in (), whereas if is a solution, this only gives one solution in , . Since the total number of solutions in is even, must not be a solution. Hence, we require that has exactly positive solutions and is not solved by
If , then is negative, and therefore cannot be the absolute value of . This means the equation's only solutions are in . There is no way for this equation to have solutions, since the quadratic can only take on each of the two values at most twice, yielding at most solutions. Hence, . also can't equal , since this would mean would solve the equation. Hence,
At this point, the equation will always have exactly positive solutions, since takes on each positive value exactly once when is restricted to positive values (graph it to see this), and are both positive. Therefore, we just need to have the remaining solutions exactly. This means the horizontal lines at each intersect the parabola in two places. This occurs when the two lines are above the parabola's vertex . Hence we have Hence, the integers satisfying the conditions are those satisfying There are such integers.
Note: Be careful of counting at the end, you may mess up and get .
Solution 4 (Algebra)
Removing the absolute value bars from the equation successively, we get The discriminant of this equation is Equating the discriminant to , we see that there will be two distinct solutions to each of the possible quadratics above only in the interval . However, the number of zeros the equation has is determined by where and intersect, namely at . When , , will have only solutions, and when , , then there will be real solutions, if they exist at all. In order to have solutions here, we thus need to ensure , so that exactly out of the possible equations of the form given above have y-intercepts below and only real solutions, while the remaining equations have solutions. This occurs when , so our final bounds are , giving us valid values of .
Remark
The graphs of and are shown here in Desmos: https://www.desmos.com/calculator/i6l98lxwpp
Move the slider around for to observe how they intersect for times.
~MRENTHUSIASM
Video Solution
https://youtu.be/6k-uR71_jg0 ~mathproblemsolvingskills.com
See Also
2021 AIME I (Problems • Answer Key • Resources) | ||
Preceded by Problem 7 |
Followed by Problem 9 | |
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.