Difference between revisions of "2020 AIME II Problems/Problem 8"

Latest revision as of 20:00, 11 January 2025

Problem

Define a sequence recursively by $f_1(x)=|x-1|$ and $f_n(x)=f_{n-1}(|x-n|)$ for integers $n>1$ . Find the least value of $n$ such that the sum of the zeros of $f_n$ exceeds $500,000$ .

Solution 1 (Official MAA)

First it will be shown by induction that the zeros of $f_n$ are the integers $a, {a+2,} {a+4,} \dots, {a + n(n-1)}$ , where $a = n - \frac{n(n-1)}2.$

This is certainly true for $n=1$ . Suppose that it is true for $n = m-1 \ge 1$ , and note that the zeros of $f_m$ are the solutions of $|x - m| = k$ , where $k$ is a nonnegative zero of $f_{m-1}$ . Because the zeros of $f_{m-1}$ form an arithmetic sequence with common difference $2,$ so do the zeros of $f_m$ . The greatest zero of $f_{m-1}$ is $m-1+\frac{(m-1)(m-2)}2 =\frac{m(m-1)}2,$ so the greatest zero of $f_m$ is $m+\frac{m(m-1)}2$ and the least is $m-\frac{m(m-1)}2$ .

It follows that the number of zeros of $f_n$ is $\frac{n(n-1)}2+1=\frac{n^2-n+2}2$ , and their average value is $n$ . The sum of the zeros of $f_n$ is $\frac{n^3-n^2+2n}2.$ Let $S(n)=n^3-n^2+2n$ , so the sum of the zeros exceeds $500{,}000$ if and only if $S(n) > 1{,}000{,}000 = 100^3\!.$ Because $S(n)$ is increasing for $n > 2$ , the values $S(100) = 1{,}000{,}000 - 10{,}000 + 200 = 990{,}200$ and $S(101)=1{,}030{,}301 - 10{,}201 + 202 = 1{,}020{,}302$ show that the requested value of $n$ is $\boxed{101}$ .

Solution 2 (Same idea, easier to see)

Starting from $f_1(x)=|x-1|$ , we can track the solutions, the number of solutions, and their sum:

$\begin{array}{c|c|c|c} n&Solutions&number&sum\\ 1&1&1&1\\ 2&1,3&2&4\\ 3&0,2,4,6&4&12\\ 4&-2,0,2...10&7&28\\ 5&-5,-3,-1...15&11&55\\ \end{array}$

It is clear that the solutions form arithmetic sequences with a difference of 2, and the negative solutions cancel out all but $n$ of the $1+\frac{n(n-1)}{2}$ solutions. Thus, the sum of the solutions is $n \cdot [1+\frac{n(n-1)}{2}]$ , which is a cubic function. (Side Note: Gergor-Newton Interpolation Formula is applicable here)

$n \cdot [1+\frac{n(n-1)}{2}]>500,000$

Multiplying both sides by $2$ ,

$n \cdot [2+n(n-1)]>1,000,000$

1 million is $10^6=100^3$ , so the solution should be close to $100$ .

100 is slightly too small, so $\boxed{101}$ works.

~ dragnin

Video Solution

https://youtu.be/g13o0wgj4p0

@@ Line 11: / Line 11: @@
 ==Solution 2 (Same idea, easier to see)==
-Starting from <math>f_1(x)=|x-1|</math>, we can track the solutions, the number of solutions, and their sum.
+Starting from <math>f_1(x)=|x-1|</math>, we can track the solutions, the number of solutions, and their sum:
-<math></math>\begin{center}
+<cmath>\begin{array}{c|c|c|c}
-\begin{tabular}{ c c c c }
+n&Solutions&number&sum\\
- <math>x</math> & Solutions & number & sum \\
+&1&1&1\\
-& 1 & 1 & 1 \\
+&1,3&2&4\\
-& 1,3 & 2 & 4 \\
+&0,2,4,6&4&12\\
-& 0,2,4,6 & 4 & 12 \\
+&-2,0,2...10&7&28\\
-& -2,0,2...10 & 7 & 28 \\
+&-5,-3,-1...15&11&55\\
-& -9,-7,-5...21 & 11 & 55 \\
+\end{array}</cmath>
-\end{tabular}
-\end{center}<math></math>
 It is clear that the solutions form arithmetic sequences with a difference of 2, and the negative solutions cancel out all but <math>n</math> of the <math>1+\frac{n(n-1)}{2}</math> solutions. Thus, the sum of the solutions is <math>n \cdot [1+\frac{n(n-1)}{2}]</math>, which is a cubic function.
+(Side Note: Gergor-Newton Interpolation Formula is applicable here)
 <math>n \cdot [1+\frac{n(n-1)}{2}]>500,000</math>
@@ Line 37: / Line 36: @@
 ~ dragnin
-==Video Solution==
-https://youtu.be/EwGydCuoHNM
-~MathProblemSolvingSkills.com
 ==Video Solution==
 https://youtu.be/g13o0wgj4p0
-~IceMatrix
 ==See Also==

2020 AIME II (Problems • Answer Key • Resources)
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