Difference between revisions of "2003 AIME I Problems/Problem 14"

Latest revision as of 13:23, 4 January 2024

Problem

The decimal representation of $m/n,$ where $m$ and $n$ are relatively prime positive integers and $m < n,$ contains the digits $2, 5$ , and $1$ consecutively and in that order. Find the smallest value of $n$ for which this is possible.

Solution

To find the smallest value of $n$ , we consider when the first three digits after the decimal point are $0.251\ldots$ .

Otherwise, suppose the number is in the form of $\frac{m}{n} = 0.X251 \ldots$ , where $X$ is a string of $k$ digits and $n$ is small as possible. Then $10^k \cdot \frac{m}{n} - X = \frac{10^k m - nX}{n} = 0.251 \ldots$ . Since $10^k m - nX$ is an integer and $\frac{10^k m - nX}{n}$ is a fraction between $0$ and $1$ , we can rewrite this as $\frac{10^k m - nX}{n} = \frac{p}{q}$ , where $q \le n$ . Then the fraction $\frac pq = 0.251 \ldots$ suffices.

Thus we have $\frac{m'}{n} = 0.251\ldots$ , or

$\frac{251}{1000} \le \frac{m'}{n} < \frac{252}{1000} \Longleftrightarrow 251n \le 1000m' < 252n \Longleftrightarrow n \le 250(4m'-n) < 2n.$

As $4m' > n$ , we know that the minimum value of $4m' - n$ is $1$ ; hence we need $250 < 2n \Longrightarrow 125 < n$ . Since $4m' - n = 1$ , we need $n + 1$ to be divisible by $4$ , and this first occurs when $n = \boxed{ 127 }$ (note that if $4m'-n > 1$ , then $n > 250$ ). Indeed, this gives $m' = 32$ and the fraction $\frac {32}{127}\approx 0.25196 \ldots$ ).

Solution 2

Rewrite the problem as having the smallest $n$ such that we can find an positive integer $m$ such that $0<\frac{m}{n}-\frac{251}{1000}<\frac{1}{1000}$ .

We can rewrite the expression as $\frac{1000m-251n}{1000n}$ , and we need $251n+x$ (where $x$ is the difference in the fraction, and ranging from (1,2,...n-1) to be $0$ mod $1000$ . We see that $n$ must be $3$ mod $4$ to have this happen (as this reduces the distance between the expression and $1000$ .

Rewriting $n$ as $4k+3$ , we get that $251(4k+3)+(4k+2)$ turns into $8k+755$ , and this has to be greater than or equal to $1000$ . The least $k$ that satisfies this is $31$ , and we consequently get that the least value of $n$ is $127$ . -dragoon -minor edits by Mathkiddie

@@ Line 16: / Line 16: @@
 ==Solution 2==
-Rewrite the problem as having the smallest <math>n</math> such that we can find an positive integer <math>m</math> such that <math>0<\frac{m}{m}-\frac{251}{1000}<\frac{1}{1000}</math>.
+Rewrite the problem as having the smallest <math>n</math> such that we can find an positive integer <math>m</math> such that <math>0<\frac{m}{n}-\frac{251}{1000}<\frac{1}{1000}</math>.
 We can rewrite the expression as <math>\frac{1000m-251n}{1000n}</math>, and we need <math>251n+x</math> (where <math>x</math> is the difference in the fraction, and ranging from (1,2,...n-1) to be <math>0</math> mod <math>1000</math>. We see that <math>n</math> must be <math>3</math> mod <math>4</math> to have this happen (as this reduces the distance between the expression and <math>1000</math>.
-Rewriting <math>n</math> as <math>4k+3</math>, we get that <math>251(4k+3)+(4k+2)</math> turns into <math>8k+755</math>, and this has to be greater than or equal to <math>1000</math>. The least <math>k</math> that satisfies this is <math>31</math>, and we consequently get that the least value of <math>n</math> is <math>127</math>. -dragoon
+Rewriting <math>n</math> as <math>4k+3</math>, we get that <math>251(4k+3)+(4k+2)</math> turns into <math>8k+755</math>, and this has to be greater than or equal to <math>1000</math>. The least <math>k</math> that satisfies this is <math>31</math>, and we consequently get that the least value of <math>n</math> is <math>127</math>. -dragoon -minor edits by Mathkiddie
 == See also ==

2003 AIME I (Problems • Answer Key • Resources)
Preceded by Problem 13	Followed by Problem 15
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Difference between revisions of "2003 AIME I Problems/Problem 14"

Latest revision as of 13:23, 4 January 2024

Contents

Problem

Solution

Solution 2

See also