Difference between revisions of "2010 AIME I Problems/Problem 12"

Revision as of 21:08, 19 December 2024

Problem

Let $m \ge 3$ be an integer and let $S = \{3,4,5,\ldots,m\}$ . Find the smallest value of $m$ such that for every partition of $S$ into two subsets, at least one of the subsets contains integers $a$ , $b$ , and $c$ (not necessarily distinct) such that $ab = c$ .

Note: a partition of $S$ is a pair of sets $A$ , $B$ such that $A \cap B = \emptyset$ , $A \cup B = S$ .

Solution 1

We claim that $243$ is the minimal value of $m$ . Let the two partitioned sets be $A$ and $B$ ; we will try to partition $3, 9, 27, 81,$ and $243$ such that the $ab=c$ condition is not satisfied. Without loss of generality, we place $3$ in $A$ . Then $9$ must be placed in $B$ , so $81$ must be placed in $A$ , and $27$ must be placed in $B$ . Then $243$ cannot be placed in any set, so we know $m$ is less than or equal to $243$ .

For $m \le 242$ , we can partition $S$ into $S \cap \{3, 4, 5, 6, 7, 8, 81, 82, 83, 84 ... 242\}$ and $S \cap \{9, 10, 11 ... 80\}$ , and in neither set are there values where $ab=c$ (since $8 < (3\text{ to }8)^2 < 81$ and $81^2>242$ and $(9\text{ to }80)^2 > 80$ ). Thus $m = \boxed{243}$ .

Solution 2

Consider ${3,4,12\} $. We could have any two of the three be together in the same set, and the third in the other set. Thus, we have$ {3,4}, {3,12}, {4,12} $. We will try to 'place' numbers in either set such that we never have$ a\cdot b = c $, until we reach a point where we MUST have$ a\cdot b =c$.

We begin with$ (Error compiling LaTeX. Unknown error_msg)\{3,12\} $. Notice that$ a,b,c $do not have to be distinct, meaning we could have$ 3\cdot 3=9 $. Thus$ 9 $must be with$ 4 $. Notice that no matter in which set$ 36 $is placed, we will be forced to have$ a\cdot b =c $, since$ 3*12=36 $and$ 4*9=36$.

We could have$ (Error compiling LaTeX. Unknown error_msg)\{4,12\} $. Similarly,$ 16 $must be with$ 3 $, and no matter to which set$ 48 $is placed into, we will be forced to have$ a \cdot b =c$.

Now we have$ (Error compiling LaTeX. Unknown error_msg)\{3,4\} $.$ 9 $must be with$ 12 $. Then$ 81 $must be with$ \{3,4\} $. Since$ 27 $can't be placed in the same set as$ \{3,4,81\} $,$ 27 $must go with$ \{9,12\} $. But then no matter where$ 243 $is placed we will have$ a\cdot b =c$.

Thus,$ (Error compiling LaTeX. Unknown error_msg)\boxed{243} $is the minimum$ m$.

Video Solution

2010 AIME I #12

MathProblemSolvingSkills.com

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 == Solution 2 ==
-Consider <math>{3,4,12}</math>. We could have any two of the three be together in the same set, and the third in the other set. Thus, we have <math>{3,4}, {3,12}, {4,12}</math>. We will try to 'place' numbers in either set such that we never have <math>a\cdot b = c</math>, until we reach a point where we MUST have <math>a\cdot b =c</math>.
+Consider \${3,4,12\}<math>. We could have any two of the three be together in the same set, and the third in the other set. Thus, we have </math>{3,4}, {3,12}, {4,12}<math>. We will try to 'place' numbers in either set such that we never have </math>a\cdot b = c<math>, until we reach a point where we MUST have </math>a\cdot b =c<math>.
-We begin with <math>{3,12}</math>. Notice that <math>a,b,c</math> do not have to be distinct, meaning we could have <math>3\cdot 3=9</math>. Thus <math>9</math> must be with <math>4</math>. Notice that no matter in which set <math>36</math> is placed, we will be forced to have <math>a\cdot b =c</math>, since <math>3*12=36</math> and <math>4*9=36</math>.
+We begin with </math>\{3,12\}<math>. Notice that </math>a,b,c<math> do not have to be distinct, meaning we could have </math>3\cdot 3=9<math>. Thus </math>9<math> must be with </math>4<math>. Notice that no matter in which set </math>36<math> is placed, we will be forced to have </math>a\cdot b =c<math>, since </math>3*12=36<math> and </math>4*9=36<math>.
-We could have <math>{4,12}</math>. Similarly, <math>16</math> must be with <math>3</math>, and no matter to which set <math>48</math> is placed into, we will be forced to have <math>a \cdot b =c</math>.
+We could have </math>\{4,12\}<math>. Similarly, </math>16<math> must be with </math>3<math>, and no matter to which set </math>48<math> is placed into, we will be forced to have </math>a \cdot b =c<math>.
-Now we have <math>{3,4}</math>. <math>9</math> must be with <math>12</math>. Then <math>81</math> must be with <math>{3,4}</math>. Since <math>27</math> can't be placed in the same set as <math>{3,4,81}</math>, <math>27</math> must go with <math>{9,12}</math>. But then no matter where <math>243</math> is placed we will have <math>a\cdot b =c</math>.
+Now we have </math>\{3,4\}<math>. </math>9<math> must be with </math>12<math>. Then </math>81<math> must be with </math>\{3,4\}<math>. Since </math>27<math> can't be placed in the same set as </math>\{3,4,81\}<math>, </math>27<math> must go with </math>\{9,12\}<math>. But then no matter where </math>243<math> is placed we will have </math>a\cdot b =c<math>.
-Thus, <math>\boxed{243}</math> is the minimum <math>m</math>.
+Thus, </math>\boxed{243}<math> is the minimum </math>m$.
 == Video Solution ==

2010 AIME I (Problems • Answer Key • Resources)
Preceded by Problem 11	Followed by Problem 13
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