Difference between revisions of "2017 IMO Problems/Problem 1"

Revision as of 01:42, 19 November 2023

Problem

For each integer $a_0 > 1$ , define the sequence $a_0, a_1, a_2, \ldots$ for $n \geq 0$ as $a_{n+1} = \begin{cases} \sqrt{a_n} & \text{if } \sqrt{a_n} \text{ is an integer,} \\ a_n + 3 & \text{otherwise.} \end{cases}$ Determine all values of $a_0$ such that there exists a number $A$ such that $a_n = A$ for infinitely many values of $n$ .

Solution

First we notice the following:

When we start with $a_0=3$ , we get $a_1=6$ , $a_2=9$ , $a_3=3$ and the pattern repeats.

When we start with $a_0=6$ , we get $a_1=9$ , $a_2=3$ , $a_3=6$ and the pattern repeats.

When we start with $a_0=9$ , we get $a_1=3$ , $a_2=6$ , $a_3=9$ and the pattern repeats.

When we start with $a_0=12$ , we get $a_1=15$ , $a_2=15$ ,..., $a_8=36$ , $a_9=6$ , $a_{10}=9$ , $a_{11}=3$ and the pattern repeats.

When this pattern $3,6,9$ repeats, this means that there exists a number $A$ such that $a_n = A$ for infinitely many values of $n$ and that number $A$ is either $3,6,$ or $9$ .

When we start with any number $a_0\not\equiv 0 (mod 3), we don't see a repeating pattern.

Therefore the claim is that$ (Error compiling LaTeX. Unknown error_msg)a_0=3k $where$ k$is a positive integer and we need to prove this claim.

When we start with$ (Error compiling LaTeX. Unknown error_msg)a_0=3k $, the next term if it is not a square is$ 3k+3 $, then$ 3k+6 $and so on until we get$ 3k+3p $where$ p $is an integer and$ (k+p)=3q^2 $where$ q $is an integer. Then the next term will be$ \sqrt(9q^2)=3q $and the pattern repeats again when$ q=k $or when$ q=3 $or$ 6$. In order for these patterns to repeat, any square in the sequence need to be a multiple of 3. This will not work with any number or square that is not a multiple of 3.

So, the answer to this problem is$ (Error compiling LaTeX. Unknown error_msg)a_0=3k\;\forall k \in \mathbb{Z}^{+}$

~Tomas Diaz. orders@tomasdiaz.com

Alternate solutions are always welcome. If you have a different, elegant solution to this problem, please add it to this page.

@@ Line 21: / Line 21: @@
 When we start with <math>a_0=12</math>, we get <math>a_1=15</math>, <math>a_2=15</math>,..., <math>a_8=36</math>, <math>a_9=6</math>, <math>a_{10}=9</math>, <math>a_{11}=3</math> and the pattern repeats.
-When this pattern <math>3,6,9</math> repeats, this means that
+When this pattern <math>3,6,9</math> repeats, this means that there exists a number <math>A</math> such that <math>a_n = A</math> for infinitely many values of <math>n</math> and that number <math>A</math> is either <math>3,6,</math> or <math>9</math>.
-So,
+When we start with any number <math>a_0\not\equiv 0 (mod 3), we don't see a repeating pattern.
+Therefore the claim is that </math>a_0=3k<math> where </math>k<math> is a positive integer and we need to prove this claim.
+When we start with </math>a_0=3k<math>, the next term if it is not a square is </math>3k+3<math>, then </math>3k+6<math> and so on until we get </math>3k+3p<math> where </math>p<math> is an integer and </math>(k+p)=3q^2<math> where </math>q<math> is an integer.  Then the next term will be </math>\sqrt(9q^2)=3q<math> and the pattern repeats again when </math>q=k<math> or when </math>q=3<math> or </math>6<math>.  In order for these patterns to repeat, any square in the sequence need to be a multiple of 3.  This will not work with any number or square that is not a multiple of 3.
+So, the answer to this problem is </math>a_0=3k\;\forall k \in \mathbb{Z}^{+}$
 ~Tomas Diaz. orders@tomasdiaz.com

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Difference between revisions of "2017 IMO Problems/Problem 1"

Revision as of 01:42, 19 November 2023

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