Difference between revisions of "2014 AIME II Problems/Problem 5"

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Problem

Real numbers $r$ and $s$ are roots of $p(x)=x^3+ax+b$ , and $r+4$ and $s-3$ are roots of $q(x)=x^3+ax+b+240$ . Find the sum of all possible values of $|b|$ .

Hint

$\boxed{\boxed{\color{blue}\textbf{USE VIÈTE'S FORMULAE!!!}}}$

Solution 1

Let $r$ , $s$ , and $-r-s$ be the roots of $p(x)$ (per Vieta's). Then $r^3 + ar + b = 0$ and similarly for $s$ . Also, $q(r+4) = (r+4)^3 + a(r+4) + b + 240 = 12r^2 + 48r + 304 + 4a = 0$

Set up a similar equation for $s$ :

$q(s-3) = (s-3)^3 + a(s-3) + b + 240 = -9s^2 + 27s + 213 - 3a = 0.$

Simplifying and adding the equations gives $3r^2 - 3s^2 + 12r + 9s + 147 = 0$

$r^2 - s^2 + 4r + 3s + 49 = 0 (*)$

Now, let's deal with the $ax$ terms. Plugging the roots $r$ , $s$ , and $-r-s$ into $p(x)$ yields a long polynomial, and plugging the roots $r+4$ , $s-3$ , and $-1-r-s$ into $q(x)$ yields another long polynomial. Equating the coefficients of x in both polynomials: $rs + (-r-s)(r+s) = (r+4)(s-3) + (-r-s-1)(r+s+1),$ which eventually simplifies to

$s = \frac{13 + 5r}{2}.$

Substitution into (*) should give $r = -5$ and $r = 1$ , corresponding to $s = -6$ and $s = 9$ , and $|b| = 330, 90$ , for an answer of $\boxed{420}$ .

Solution 2

The roots of $p(x)$ are $r$ , $s$ , and $-r-s$ since they sum to $0$ by Vieta's Formula (co-efficient of $x^2$ term is $0$ ).

Similarly, the roots of $q(x)$ are $r + 4$ , $s - 3$ , and $-r-s-1$ , as they too sum to $0$ .

Then:

$a = rs+r(-r-s)+s(-r-s) = rs-(r+s)^2$ and $-b = rs(-r-s)$ from $p(x)$ and

$a=(r+4)(s-3)+(r+4)(-r-s-1)+(s-3)(-r-s-1) = (r+4)(s-3)-(r+s+1)^2$ and $-(b+240)=(r+4)(s-3)(-r-s-1)$ from $q(x)$ .

From these equations, we can write that $rs-(r+s)^2 = (r+4)(s-3)-(r+s+1)^2 = a$ and simplifying gives $2s-5r-13=0 \Rightarrow s = \frac{5r+13}{2}.$

We now move to the other two equations regarding the product of the roots. We see that we can cancel a negative from both sides to get $rs(r+s) = b$ $(r+4)(s-3)(r+s+1)=b + 240.$ Subtracting the first equation from the second equation gives us $(r+4)(s-3)(r+s+1) - rs(r+s) = 240$ .

Expanding, simplifying, substituting $s = \frac{5r+13}{2}$ , and simplifying some more yields the simple quadratic $r^2 + 4r - 5 = 0$ , so $r = -5, 1$ . Then $s = -6, 9$ .

Finally, we substitute back into $b=rs(r+s)$ to get $b = (-5)(-6)(-5-6) = -330$ , or $b = (1)(9)(1 + 9) = 90$ .

The answer is $|-330|+|90| = \boxed{420}$ .

Solution 3

By Vieta's, we know that the sum of roots of $p(x)$ is $0$ . Therefore, the roots of $p$ are $r, s, -r-s$ . By similar reasoning, the roots of $q(x)$ are $r + 4, s - 3, -r - s - 1$ . Thus, $p(x) = (x - r)(x - s)(x + r + s)$ and $q(x) = (x - r - 4)(x - s + 3)(x + r + s + 1)$ .

Since $p(x)$ and $q(x)$ have the same coefficient for $x$ , we can go ahead and match those up to get $\begin{align*} rs - r(r + s) - s(r + s) &= (r + 4)(s - 3) - (r + 4)(r + s + 1) - (s - 3)(r + s + 1) \\ 0 &= -13 - 5r + 2s \\ s &= \frac{5r + 13}{2} \end{align*}$

At this point, we can go ahead and compare the constant term in $p(x)$ and $q(x)$ . Doing so is certainly valid, but we can actually do this another way. Notice that $p(s) = 0$ . Therefore, $q(s) = 240$ . If we plug that into our expression, we get that $\begin{align*} q(s) &= 3(s - r - 4)(r + 2s + 1) \\ 240 &= 3(s - r - 4)(r + 2s + 1) \\ 240 &= 3\left( \frac{3r + 5}{2} \right)(6r + 14) \\ 80 &= (3r + 5)(3r + 7) \\ 0 &= r^2 + 4r - 5 \end{align*}$ This tells us that $(r, s) = (1, 9)$ or $(-5, -6)$ . Since $-b$ is the product of the roots, we have that the two possibilities are $1 \cdot 9 \cdot (-10) = -90$ and $(-5)(-6)11 = 330$ . Adding the absolute values of these gives us $\boxed{420}$ .

@@ Line 3: / Line 3: @@
 ==Hint==
-<cmath>\textbf{USE VIÈTE'S FORMULAE!!!}</cmath>
+<cmath>\boxed{\boxed{\color{blue}\textbf{USE VIÈTE'S FORMULAE!!!}}}</cmath>
 ==Solution 1==
 Let <math>r</math>, <math>s</math>, and <math>-r-s</math> be the roots of <math>p(x)</math> (per Vieta's). Then <math>r^3 + ar + b = 0</math> and similarly for <math>s</math>. Also,

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