Difference between revisions of "2023 AIME I Problems/Problem 9"

Revision as of 17:36, 8 February 2023

Problem 9

Find the number of cubic polynomials $p(x) = x^3 + ax^2 + bx + c$ , where $a$ , $b$ , and $c$ are integers in $\{ -20, -19, -18, \dots , 18, 19, 20 \}$ , such that there is a unique integer $m \neq 2$ with $p(m) = p(2).$

Solution 1

Plugging $2$ and $m$ into $P(x)$ and equating them, we get $8+4a+2b+c = m^3+am^2+bm+c$ . Rearranging, we have $(m^3-8) + (m^2 - 4)a + (m-2)b = 0.$ Note that the value of $c$ won't matter as it can be anything in the provided range, giving a total of $41$ possible choices for $c.$ So what we just need to do is to just find the number of ordered pairs $(a, b)$ that work, and multiply it by $41.$ We can start by first dividing both sides by $m-2.$ (Note that this is valid since $m\neq2:$ $m^2 + 2m + 4 + (m+2)a + b = 0.$ We can rearrange this so it is a quadratic in $m$ : $m^2 + (a+2)m + (4 + 2a + b) = 0.$ Remember that $m$ has to be unique and not equal to $2.$ We can split this into two cases: case $1$ being that $m$ has exactly one solution, and it isn't equal to $2$ ; case $2$ being that $m$ has two solutions, one being equal to $2,$ but the other is a unique solution not equal to $2.$

$\textbf{Case 1:}$

There is exactly one solution for $m,$ and that solution is not $2.$ This means that the discriminant of the quadratic equation is $0,$ using that, we have $(a+2)^2 = 4(4 + 2a + b),$ rearranging in a neat way, we have $(a-2)^2 = 4(4 + b)\Longrightarrow a = 2\pm2\sqrt{4+b}.$ Using the fact that $4+b$ must be a perfect square, we can easily see that the values for $b$ can be $-4, -3, 0, 5,$ and $12.$ Also since it's a " $\pm$ " there will usually be $2$ solutions for $a$ for each value of $b.$ The two exceptions for this would be if $b = -4$ and $b = 12.$ For $b=-4$ because it would be a $\pm0,$ which only gives one solution, instead of two. And for $b=12$ because then $a = -6$ and the solution for $m$ would equal to $2,$ and we don't want this. (We can know this by putting the solutions back into the quadratic formula).

So we have $5$ solutions for $b,$ each of which give $2$ values for $a,$ except for $2,$ which only give one. So in total, there are $5*10 - 2 = 8$ ordered pairs of $(a,b)$ in this case.

$\textbf{Case 2:}$

$m$ has two solutions, but exactly one of them isn't equal to $2.$ This ensures that $1$ of the solutions is equal to $2.$

Let $r$ be the other value of $m$ that isn't $2.$ By Vieta: $\begin{align*} r+2 &= -a-2\\ 2r &= 4+2a+b. \end{align*}$ From the first equation, we subtract both sides by $2$ and double both sides to get $2r = -2a - 8$ which also equals to $4+2a+b$ from the second equation. Equating both, we have $4a + b + 12 = 0.$ We can easily count that there would be $11$ ordered pairs $(a,b)$ that satisfy that.

However, there's an outlier case in which $r$ happens to also equal to $2,$ and we don't want that. We can reverse engineer and find out that $r=2$ when $(a,b) = (-6, 12),$ which we overcounted. So we subtract by one and we conclude that there are $10$ ordered pairs of $(a,b)$ that satisfy this case.

This all shows that there are a total of $8+10 = 18$ amount of ordered pairs $(a,b).$ Multiplying this by $41$ (the amount of values for $c$ ) we get $18\cdot41=\boxed{738}$ as our final answer.

~s214425

Solution 2

$p(x)-p(2)$ is a cubic with two integral real roots, therefore it has three real roots, which are all integers. There are exactly two distinct roots, so either $p(x)=p(2)+(x-2)^2(x-m)$ or $p(x)=p(2)+(x-2)(x-m)^2$ with $m\neq 2$ . In the first case $p(x)=x^3-(4+m)x^2+(4+4m)x-4m+p(2)$ , so $m$ can be $-6,-5,-4,-3,-2,-1,0,1,3,4$ and $-4m+p(2)$ can be any integer from $-20$ to $20$ , giving $410$ polynomials. In the second case $p(x)=x^3-(1+2m)x^2+(4m+m^2)x-2m^2+p(2)$ , and $m$ can be $-6,-5,-4,-3,-2,-1,0,1$ and $-4m+p(2)$ can be any integer from $-20$ to $20$ , giving 328 polynomials. The total is $\boxed{738}$ .

~EVIN-

@@ Line 21: / Line 21: @@
 <math>m</math> has two solutions, but exactly one of them isn't equal to <math>2.</math> This ensures that <math>1</math> of the solutions is equal to <math>2.</math>
-Let <math>r</math> be the other value of <math>m</math> that isn't <math>2.</math> By Vieta: <cmath>r+2 = -a-2</cmath> <cmath>2r = 4+2a+b.</cmath> From the first equation, we subtract both sides by <math>2</math> and double both sides to get <math>2r = -2a - 8</math> which also equals to <math>4+2a+b</math> from the second equation. Equating both, we have <math>4a + b + 12 = 0.</math> We can easily count that there would be <math>11</math> ordered pairs <math>(a,b)</math> that satisfy that.
+Let <math>r</math> be the other value of <math>m</math> that isn't <math>2.</math> By Vieta:
+<cmath>\begin{align*}
+r+2 &= -a-2\\
+r &= 4+2a+b.
+\end{align*}</cmath> From the first equation, we subtract both sides by <math>2</math> and double both sides to get <math>2r = -2a - 8</math> which also equals to <math>4+2a+b</math> from the second equation. Equating both, we have <math>4a + b + 12 = 0.</math> We can easily count that there would be <math>11</math> ordered pairs <math>(a,b)</math> that satisfy that.
 However, there's an outlier case in which <math>r</math> happens to also equal to <math>2,</math> and we don't want that. We can reverse engineer and find out that <math>r=2</math> when <math>(a,b) = (-6, 12),</math> which we overcounted. So we subtract by one and we conclude that there are <math>10</math> ordered pairs of <math>(a,b)</math> that satisfy this case.

2023 AIME I (Problems • Answer Key • Resources)
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Difference between revisions of "2023 AIME I Problems/Problem 9"

Revision as of 17:36, 8 February 2023

Contents

Problem 9

Solution 1

Solution 2

See also