Difference between revisions of "2023 AIME II Problems/Problem 15"

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(adding solution based on a binary interpretation)
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~[[User:Bxiao31415|Bxiao31415]]
 
~[[User:Bxiao31415|Bxiao31415]]
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== Solution (Binary Interpretation, Computer Scientists' Playground) ==
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We first check that <math>\gcd(23, 2^n) = 1</math> hence we are always seeking a unique modular inverse of <math>23</math>, <math>b_n</math>, such that <math>a_n \equiv 23b_n \equiv 1 \mod{2^n}</math>.
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Now that we know that <math>b_n</math> is unique, we proceed to recast this problem in binary. This is convenient because <math>x \mod{2^n}</math> is simply the last <math>n</math>-bits of <math>x</math> in binary, and if <math>x \equiv 1 \mod{2^n}</math>, it means that of the last <math>n</math> bits of <math>x</math>, only the rightmost bit (henceforth <math>0</math>th bit) is <math>1</math>.
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Also, multiplication in binary can be thought of as adding shifted copies of the multiplicand. For example:
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<cmath>
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\begin{align}
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10111_2 \times 1011_2 &= 10111_2 \times (1000_2 + 10_2 + 1_2) \\
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              &= 10111000_2 + 101110_2 + 10111_2 \\
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              &= 11111101_2
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\end{align}
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</cmath>
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Now note <math>23 = 10111_2</math>, and recall that our objective is to progressively zero out the <math>n</math> leftmost bits of <math>a_n = 10111_2 \times b_n</math> except for the <math>0</math>th bit.
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Write <math>b_n = \underline{c_{n-1}\cdots c_2c_1c_0}_2</math>, we note that <math>c_0</math> uniquely defines the <math>0</math>th bit of <math>a_n</math>, and once we determine <math>c_0</math>, <math>c_1</math> uniquely determines the <math>1</math>st bit of <math>a_n</math>, so on and so forth.
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For example, <math>c_0 = 1</math> satisfies <math>a_1 \equiv10111_2 \times 1_2 \equiv 1 \mod{10_2}</math>
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Next, we note that the second bit of <math>a_1</math> is <math>1</math>, so we must also have <math>c_1 = 1</math> in order to zero it out, giving
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<cmath>a_2 \equiv 10111_2 \times 11_2 \equiv 101110_2 + a_1 \equiv 1000101_2 \equiv 01_2 \mod{100_2}</cmath>
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<math>a_{n+1} = a_{n}</math> happens precisely when <math>c_n = 0</math>. In fact we can see this in action by working out <math>a_3</math>. Note that <math>a_2</math> has 1 on the <math>2</math>nd bit, so we must choose <math>c_2 = 1</math>. This gives
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<cmath>a_3 \equiv 10111_2 \times 111_2 \equiv 1011100_2 + a_2 \equiv 10100001_2 \equiv 001_2 \mod{1000_2}</cmath>
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Note that since the <math>3</math>rd and <math>4</math>th bit are <math>0</math>, <math>c_3 = c_4 = 0</math>, and this gives <math>a_3 = a_4 = a_5</math>.
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It may seem that this process will take forever, but note that <math>23 = 10111_2</math> has <math>4</math> bits behind the leading digit, and in the worst case, the leading digits of <math>a_n</math> will have a cycle length of at most <math>16</math>. In fact, we find that the cycle length is <math>11</math>, and in the process found that <math>a_3 = a_4 = a_5</math>, <math>a_6 = a_7</math>, and <math>a_{11} = a_{12}</math>.
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Since we have <math>90</math> complete cycles of length <math>11</math>, and the last partial cycle yields <math>a_{993} = a_{994} = a_{995}</math> and <math>a_{996} = a_{997}</math>, we have a total of <math>90 \times 4 + 3 = \boxed{363}</math> values of <math>n \le 1000</math> such that <math>a_n = a_{n+1}</math>
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~ cocoa @ https://www.corgillogical.com
  
 
== See also ==
 
== See also ==
 
{{AIME box|year=2023|num-b=14|after=Last Problem|n=II}}
 
{{AIME box|year=2023|num-b=14|after=Last Problem|n=II}}
 
{{MAA Notice}}
 
{{MAA Notice}}

Revision as of 18:55, 16 February 2023

For each positive integer $n$ let $a_n$ be the least positive integer multiple of $23$ such that $a_n \equiv 1 \pmod{2^n}.$ Find the number of positive integers $n$ less than or equal to $1000$ that satisfy $a_n = a_{n+1}.$

Solution

Denote $a_n = 23 b_n$. Thus, for each $n$, we need to find smallest positive integer $k_n$, such that \[ 23 b_n = 2^n k_n + 1 . \]

Thus, we need to find smallest $k_n$, such that \[ 2^n k_n \equiv - 1 \pmod{23} . \]

Now, we find the smallest $m$, such that $2^m \equiv 1 \pmod{23}$. We must have $m | \phi \left( 23 \right)$. That is, $m | 22$. We find $m = 11$.

Therefore, for each $n$, we need to find smallest $k_n$, such that \[ 2^{{\rm Rem} \left( n , 11 \right)} k_n \equiv - 1 \pmod{23} . \]

We have the following results: \begin{enumerate} \item If ${\rm Rem} \left( n , 11 \right) = 0$, then $k_n = 22$ and $b_n = 1$. \item If ${\rm Rem} \left( n , 11 \right) = 1$, then $k_n = 11$ and $b_n = 1$. \item If ${\rm Rem} \left( n , 11 \right) = 2$, then $k_n = 17$ and $b_n = 3$. \item If ${\rm Rem} \left( n , 11 \right) = 3$, then $k_n = 20$ and $b_n = 7$. \item If ${\rm Rem} \left( n , 11 \right) = 4$, then $k_n = 10$ and $b_n = 7$. \item If ${\rm Rem} \left( n , 11 \right) = 5$, then $k_n = 5$ and $b_n = 7$. \item If ${\rm Rem} \left( n , 11 \right) = 6$, then $k_n = 14$ and $b_n = 39$. \item If ${\rm Rem} \left( n , 11 \right) = 7$, then $k_n = 7$ and $b_n = 39$. \item If ${\rm Rem} \left( n , 11 \right) = 8$, then $k_n = 15$ and $b_n = 167$. \item If ${\rm Rem} \left( n , 11 \right) = 9$, then $k_n = 19$ and $b_n = 423$. \item If ${\rm Rem} \left( n , 11 \right) = 10$, then $k_n = 21$ and $b_n = 935$. \end{enumerate}

Therefore, in each cycle, $n \in \left\{ 11 l , 11l + 1 , \cdots , 11l + 10 \right\}$, we have $n = 11l$, $11l + 3$, $11l + 4$, $11l + 6$, such that $b_n = b_{n+1}$. That is, $a_n = a_{n+1}$. At the boundary of two consecutive cycles, $b_{11L + 10} \neq b_{11 \left(l + 1 \right)}$.

We have $1000 = 90 \cdot 11 + 10$. Therefore, the number of feasible $n$ is $91 \cdot 4 - 1 = \boxed{\textbf{(363) }}$.

~Steven Chen (Professor Chen Education Palace, www.professorchenedu.com)

Solution 2

Observe that if $a_{n-1}$ is divisible by $2^n$, $a_n = a_{n-1}$. If not, $a_n = a_{n-1} + 23 \cdot 2^{n-1}$.

This encourages us to let $b_n = (a_n - 1)/2^n$. Rewriting the above equations, we have \[b_n = \begin{cases} b_{n-1}/2 & \text{if } 2 | (b_{n-1}+23)/2 \\ 1 &\text{if } 2\not\vert b_{n-1} \end{cases}\] Now, we start listing. We know that $b_1 = 11$, so $b_2 = 17$, $b_3 = 20$, $b_4 = 10$, $b_5 = 5$, $b_6 = 14$, $b_7 = 7$, $b_8 = 15$, $b_9 = 19$, $b_{10} = 21$, $b_{11} = 22$, $b_{12} = 1$. Hence the sequence is periodic with period 11. Note that $a_n = a_{n+1}$ if and only if $b_n = b_{n+1}/2$, i.e. $b_n$ is even. This occurrs when $n$ is congruent to 0, 3, 4 or 6 mod 11.

From 1 to $1001 = 91 \times 11$, there are $91 \times 4 = 364$ values of $n$. Since $1001$ satisfies the criteria, we subtract 1 to get $\fbox{363}$, and we're done!

~Bxiao31415


Solution (Binary Interpretation, Computer Scientists' Playground)

We first check that $\gcd(23, 2^n) = 1$ hence we are always seeking a unique modular inverse of $23$, $b_n$, such that $a_n \equiv 23b_n \equiv 1 \mod{2^n}$.


Now that we know that $b_n$ is unique, we proceed to recast this problem in binary. This is convenient because $x \mod{2^n}$ is simply the last $n$-bits of $x$ in binary, and if $x \equiv 1 \mod{2^n}$, it means that of the last $n$ bits of $x$, only the rightmost bit (henceforth $0$th bit) is $1$.

Also, multiplication in binary can be thought of as adding shifted copies of the multiplicand. For example:

\begin{align} 10111_2 \times 1011_2 &= 10111_2 \times (1000_2 + 10_2 + 1_2) \\               &= 10111000_2 + 101110_2 + 10111_2 \\               &= 11111101_2 \end{align}

Now note $23 = 10111_2$, and recall that our objective is to progressively zero out the $n$ leftmost bits of $a_n = 10111_2 \times b_n$ except for the $0$th bit.

Write $b_n = \underline{c_{n-1}\cdots c_2c_1c_0}_2$, we note that $c_0$ uniquely defines the $0$th bit of $a_n$, and once we determine $c_0$, $c_1$ uniquely determines the $1$st bit of $a_n$, so on and so forth.

For example, $c_0 = 1$ satisfies $a_1 \equiv10111_2 \times 1_2 \equiv 1 \mod{10_2}$ Next, we note that the second bit of $a_1$ is $1$, so we must also have $c_1 = 1$ in order to zero it out, giving

\[a_2 \equiv 10111_2 \times 11_2 \equiv 101110_2 + a_1 \equiv 1000101_2 \equiv 01_2 \mod{100_2}\]

$a_{n+1} = a_{n}$ happens precisely when $c_n = 0$. In fact we can see this in action by working out $a_3$. Note that $a_2$ has 1 on the $2$nd bit, so we must choose $c_2 = 1$. This gives

\[a_3 \equiv 10111_2 \times 111_2 \equiv 1011100_2 + a_2 \equiv 10100001_2 \equiv 001_2 \mod{1000_2}\]

Note that since the $3$rd and $4$th bit are $0$, $c_3 = c_4 = 0$, and this gives $a_3 = a_4 = a_5$.


It may seem that this process will take forever, but note that $23 = 10111_2$ has $4$ bits behind the leading digit, and in the worst case, the leading digits of $a_n$ will have a cycle length of at most $16$. In fact, we find that the cycle length is $11$, and in the process found that $a_3 = a_4 = a_5$, $a_6 = a_7$, and $a_{11} = a_{12}$.

Since we have $90$ complete cycles of length $11$, and the last partial cycle yields $a_{993} = a_{994} = a_{995}$ and $a_{996} = a_{997}$, we have a total of $90 \times 4 + 3 = \boxed{363}$ values of $n \le 1000$ such that $a_n = a_{n+1}$

~ cocoa @ https://www.corgillogical.com

See also

2023 AIME II (ProblemsAnswer KeyResources)
Preceded by
Problem 14
Followed by
Last Problem
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
All AIME Problems and Solutions

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