Difference between revisions of "2015 AIME I Problems/Problem 14"

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==Solution 1==
 
==Solution 1==
  
Let <math>n\ge 2</math> and define <math>a(n) = \left\lfloor \sqrt n \right\rfloor</math>. For <math>2\le n \le 1000</math>, we have <math>1\le a(n)\le 31</math>. For each <math>a</math> there are <math>2a+1</math> corresponding values of <math>n</math>: i.e., <math>n\in \{a^2, \ldots , (a+1)^2-1\}</math>.
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Let <math>n\ge 2</math> and define <math>a(n) = \left\lfloor \sqrt n \right\rfloor</math>. For <math>2\le n \le 1000</math>, we have <math>1\le a(n)\le 31</math>.  
  
 
For <math>a^2 \le x < (a+1)^2</math> we have <math>y=ax</math>. Thus <math>A(n+1)-A(n)=a(n+\tfrac 12) = \Delta_n</math> (say), and <math>\Delta_n</math> is an integer if <math>a</math> is even; otherwise <math>\Delta_n</math> is an integer plus <math>\tfrac 12</math>.
 
For <math>a^2 \le x < (a+1)^2</math> we have <math>y=ax</math>. Thus <math>A(n+1)-A(n)=a(n+\tfrac 12) = \Delta_n</math> (say), and <math>\Delta_n</math> is an integer if <math>a</math> is even; otherwise <math>\Delta_n</math> is an integer plus <math>\tfrac 12</math>.
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<cmath>
 
<cmath>
 
\begin{align}
 
\begin{align}
a(n)\equiv 0\pmod 4 \qquad &\Longrightarrow \qquad A(n) \in \mathbb{Z} \textrm{ for all } n,\\
 
 
a(n)\equiv 1\pmod 4 \qquad &\Longrightarrow \qquad A(n) \in \mathbb{Z} \textrm{ for even } n, \\
 
a(n)\equiv 1\pmod 4 \qquad &\Longrightarrow \qquad A(n) \in \mathbb{Z} \textrm{ for even } n, \\
 
a(n)\equiv 2\pmod 4 \qquad &\Longrightarrow \qquad A(n) \not\in \mathbb{Z} \textrm{  for any } n, \\
 
a(n)\equiv 2\pmod 4 \qquad &\Longrightarrow \qquad A(n) \not\in \mathbb{Z} \textrm{  for any } n, \\
a(n)\equiv 3\pmod 4 \qquad &\Longrightarrow \qquad A(n) \in \mathbb{Z} \textrm{ for odd  } n.
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a(n)\equiv 3\pmod 4 \qquad &\Longrightarrow \qquad A(n) \in \mathbb{Z} \textrm{ for odd  } n, \\
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a(n)\equiv 0\pmod 4 \qquad &\Longrightarrow \qquad A(n) \in \mathbb{Z} \textrm{ for all } n.
 
\end{align}
 
\end{align}
 
</cmath>
 
</cmath>
  
The number of values of <math>n</math> corresponding to <math>(1)</math> (i.e., <math>a(n)\equiv 0\pmod 4</math>) is given by <cmath>\sum_{\substack{a=4k \\ a\le 31}}(2a+1) = \sum_{k=1}^7 (8k+1)=231.</cmath>
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For each <math>a</math> there are <math>2a+1</math> corresponding values of <math>n</math>: i.e., <math>n\in \{a^2, \ldots , (a+1)^2-1\}</math>.
  
The cases <math>(2)</math> and <math>(4)</math> combine to account for half the values of <math>n</math> corresponding to odd values of <math>a(n)</math>; i.e.,
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Thus, the number of values of <math>n</math> corresponding to <math>(4)</math> (i.e., <math>a(n)\equiv 0\pmod 4</math>) is given by <cmath>\sum_{\substack{a=4k \\ a\le 31}}(2a+1) = \sum_{k=1}^7 (8k+1)=231.</cmath>
<cmath>\frac 12 \cdot \sum_{\substack{a=2k+1 \\ a\le 31}} (2a+1) = \sum_{k=0}^{15} (2k+\tfrac 32) = 264</cmath>However, this also includes the odd integers in <math>\{1001, \ldots , 1023\}</math>. Subtracting <math>12</math> to account for these, we get the  number of values of <math>n</math> corresponding to cases <math>(2)</math> and <math>(3)</math> to be <math>264-12=252</math>.
 
  
Adding the contributions from all cases we get our answer to be <math>231+252= 483</math>.
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The cases <math>(1)</math> and <math>(3)</math> combine to account for half the values of <math>n</math> corresponding to odd values of <math>a(n)</math>; i.e.,
 +
<cmath>\frac 12 \cdot \sum_{\substack{a=2k+1 \\ a\le 31}} (2a+1) = \sum_{k=0}^{15} (2k+\tfrac 32) = 264</cmath>However, this also includes the odd integers in <math>\{1001, \ldots , 1023\}</math>. Subtracting <math>12</math> to account for these, we get the  number of values of <math>n</math> corresponding to cases <math>(1)</math> and <math>(3)</math> to be <math>264-12=252</math>.
 +
 
 +
Adding the contributions from all cases we get our answer to be <math>231+252= \boxed{483}</math>.
  
 
==Solution 2==
 
==Solution 2==
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Even summation of working cases: <math>9+17+25+...+57 = 231</math>.
 
Even summation of working cases: <math>9+17+25+...+57 = 231</math>.
 
Odd summation: <math>1+4+5+8+9+12...+29</math> and plus the <math>20</math> cases from <math>n=[962, 1000]</math>: <math>252</math>. Answer is <math>\boxed{483}</math>.
 
Odd summation: <math>1+4+5+8+9+12...+29</math> and plus the <math>20</math> cases from <math>n=[962, 1000]</math>: <math>252</math>. Answer is <math>\boxed{483}</math>.
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==Video Solution==
 +
https://youtu.be/tup11-90Bqw
 +
 +
~MathProblemSolvingSkills.com
 +
 +
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==See Also==
 
==See Also==

Latest revision as of 17:58, 5 August 2023

Problem

For each integer $n \ge 2$, let $A(n)$ be the area of the region in the coordinate plane defined by the inequalities $1\le x \le n$ and $0\le y \le x \left\lfloor \sqrt x \right\rfloor$, where $\left\lfloor \sqrt x \right\rfloor$ is the greatest integer not exceeding $\sqrt x$. Find the number of values of $n$ with $2\le n \le 1000$ for which $A(n)$ is an integer.

Solution 1

Let $n\ge 2$ and define $a(n) = \left\lfloor \sqrt n \right\rfloor$. For $2\le n \le 1000$, we have $1\le a(n)\le 31$.

For $a^2 \le x < (a+1)^2$ we have $y=ax$. Thus $A(n+1)-A(n)=a(n+\tfrac 12) = \Delta_n$ (say), and $\Delta_n$ is an integer if $a$ is even; otherwise $\Delta_n$ is an integer plus $\tfrac 12$.

If $a=1$, $n\in \{1,2,3\}$ and $\Delta_n$ is of the form $k(n)+\tfrac 12$ so $A(n)$ is an integer when $n$ is even.

If $a=2$, $n\in\{4,\ldots , 8\}$ and $\Delta_n$ is an integer for all $n$. Since $A(3)$ is not an integer, so $A(n)$ is not an integer for any $n$.

If $a=3$, $n\in\{9,\ldots , 15\}$ and $\Delta_n$ is of the form $k(n)+\tfrac 12$. Since $A(8)$ is of the form $k+\tfrac 12$ so $A(n)$ is an integer only when $n$ is odd.

If $a=4$, $n\in\{16,\ldots , 24\}$ and $\Delta_n$ is an integer for all $n$. Since $A(15)$ is an integer so $A(n)$ is an integer for all $n$.

Now we are back to where we started; i.e., the case $a=5$ will be the same as $a=1$ and so on. Thus, \begin{align} a(n)\equiv 1\pmod 4 \qquad &\Longrightarrow \qquad A(n) \in \mathbb{Z} \textrm{ for even } n, \\ a(n)\equiv 2\pmod 4 \qquad &\Longrightarrow \qquad A(n) \not\in \mathbb{Z} \textrm{  for any } n, \\ a(n)\equiv 3\pmod 4 \qquad &\Longrightarrow \qquad A(n) \in \mathbb{Z} \textrm{ for odd  } n, \\ a(n)\equiv 0\pmod 4 \qquad &\Longrightarrow \qquad A(n) \in \mathbb{Z} \textrm{ for all } n. \end{align}

For each $a$ there are $2a+1$ corresponding values of $n$: i.e., $n\in \{a^2, \ldots , (a+1)^2-1\}$.

Thus, the number of values of $n$ corresponding to $(4)$ (i.e., $a(n)\equiv 0\pmod 4$) is given by \[\sum_{\substack{a=4k \\ a\le 31}}(2a+1) = \sum_{k=1}^7 (8k+1)=231.\]

The cases $(1)$ and $(3)$ combine to account for half the values of $n$ corresponding to odd values of $a(n)$; i.e., \[\frac 12 \cdot \sum_{\substack{a=2k+1 \\ a\le 31}} (2a+1) = \sum_{k=0}^{15} (2k+\tfrac 32) = 264\]However, this also includes the odd integers in $\{1001, \ldots , 1023\}$. Subtracting $12$ to account for these, we get the number of values of $n$ corresponding to cases $(1)$ and $(3)$ to be $264-12=252$.

Adding the contributions from all cases we get our answer to be $231+252= \boxed{483}$.

Solution 2

By considering the graph of this function, it is shown that the graph is composed of trapezoids ranging from $a^2$ to $(a+1)^2$ with the top made of diagonal line $y=ax$. The width of each trapezoid is $3, 5, 7$, etc. Whenever $a$ is odd, the value of $A(n)$ increases by an integer value, plus $\frac{1}{2}$. Whenever $a$ is even, the value of $A(n)$ increases by an integer value. Since each trapezoid always has an odd width, every value of $n$ is not an integer when $a \pmod{4} \equiv 2$, and is an integer when $a \pmod{4} \equiv 0$. Every other value is an integer when $a$ is odd. Therefore, it is simply a matter of determining the number of values of $n$ where $a \pmod{4} \equiv 0$ ($(5^2-4^2)+(9^2-8^2)+...+(29^2-28^2)$), and adding the number of values of $n$ where $a$ is odd ($\frac{(2^2-1^2)+(4^2-3^2)+...+(30^2-29^2)+(1000-31^2)}{2}$). Adding the two values gives $231+252=\boxed{483}$.

"Step" Solution

First, draw a graph of the function. Note that it is just a bunch of line segments. Since we only need to know whether or not $A(n)$ is an integer, we can take the area of each piece from some $x$ to $x+1$ (mod 1), aka the piece from $2$ to $3$ has area $\frac{1}{2} (\mod 1)$. There are some patterns. Every time we increase $n$ starting with $2$, we either add $0 (\mod 1)$ or $\frac{1}{2} (\mod 1)$. We look at $\lfloor \sqrt{x} \rfloor$ for inspiration. Every time this floor (which is really the slope) is odd, there is always an addition of $\frac{1}{2} (\mod 1)$, and whenever that slope is even, that addition is zero.

Take a few cases. For slope $=1$, we see that only one value satisfies. Because the last value, $n=4$, fails, and the numbers $n$ which have a slope of an even number don't change this modulus, all these do not satisfy the criterion. The pattern then comes back to the odds, and this time $\lfloor \frac{7}{2} \rfloor + 1 = 4$ values work. Since the work/fail pattern alternates, all the $n$s with even slope, $[17, 25]$, satisfy the criterion. This pattern is cyclic over period 4 of slopes.

Even summation of working cases: $9+17+25+...+57 = 231$. Odd summation: $1+4+5+8+9+12...+29$ and plus the $20$ cases from $n=[962, 1000]$: $252$. Answer is $\boxed{483}$.


Video Solution

https://youtu.be/tup11-90Bqw

~MathProblemSolvingSkills.com



See Also

2015 AIME I (ProblemsAnswer KeyResources)
Preceded by
Problem 13
Followed by
Problem 15
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
All AIME Problems and Solutions

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