Difference between revisions of "1994 IMO Problems/Problem 1"

Latest revision as of 00:28, 22 November 2023

Let $m$ and $n$ be two positive integers. Let $a_1$ , $a_2$ , $\ldots$ , $a_m$ be $m$ different numbers from the set $\{1, 2,\ldots, n\}$ such that for any two indices $i$ and $j$ with $1\leq i \leq j \leq m$ and $a_i + a_j \leq n$ , there exists an index $k$ such that $a_i + a_j = a_k$ . Show that $\frac{a_1+a_2+...+a_m}{m} \ge \frac{n+1}{2}$ .

Solution

Let $a_1, a_2, \dots a_m$ satisfy the given conditions. We will prove that for all $j, 1 \le j \le m,$

$a_j+a_{m-j+1} \ge n+1$

WLOG, let $a_1 < a_2 < \dots < a_m$ . Assume that for some $j, 1 \le j \le m,$

$a_j + a_{m-j+1} \le n$

This implies, for each $i, 1 \le i \le j,$ $a_i + a_{m-j+1} \le n$ because $a_i \le a_j$

For each of these values of i, we must have $a_i + a_{m-j+1} = a_{k_i}$ such that $a_{k_i}$ is a member of the sequence for each $i$ . Because $a_i > 0, a_{k_i} > a_{m-j+1}$ . Combining all of our conditions we have that each of $k_i$ must be distinct integers such that $m-j+1 < k_i \le m$

However, there are $j$ distinct $k_i$ , but only $j-1$ integers satisfying the above inequality, so we have a contradiction. Our assumption that $a_j + a_{m-j+1} \le n$ was false, so $a_j + a_{m-j+1} \ge n+1$ for all $j$ such that $1 \le j \le m$ Summing these inequalities together for $1 \le j \le m$ gives $2(a_1+a_2+ \dots a_m) \ge m(n+1)$ which rearranges to $\frac{a_1+a_2+ \dots a_m}{m} \ge \frac{n+1}{2}$

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+Let <math> m</math> and <math> n</math> be two positive integers. Let <math> a_1</math>, <math> a_2</math>, <math> \ldots</math>, <math> a_m</math> be <math> m</math> different numbers from the set <math> \{1, 2,\ldots, n\}</math> such that for any two indices <math> i</math> and <math> j</math> with <math> 1\leq i \leq j \leq m</math> and <math> a_i + a_j \leq n</math>, there exists an index <math> k</math> such that <math> a_i + a_j = a_k</math>. Show that
+<cmath>\frac{a_1+a_2+...+a_m}{m} \ge \frac{n+1}{2}</cmath>.
+==Solution==
+Let <math>a_1, a_2, \dots a_m</math> satisfy the given conditions. We will prove that for all <math>j, 1 \le j \le m,</math>
+<cmath>a_j+a_{m-j+1} \ge n+1</cmath>
+WLOG, let <math>a_1 < a_2 < \dots < a_m</math>. Assume that for some <math>j, 1 \le j \le m,</math>
+<cmath> a_j + a_{m-j+1} \le n</cmath>
+This implies, for each <math>i, 1 \le i \le j,</math>
+<cmath> a_i + a_{m-j+1} \le n </cmath>
+because <math>a_i \le a_j</math>
+For each of these values of i, we must have <math>a_i + a_{m-j+1} = a_{k_i}</math> such that <math>a_{k_i}</math> is a member of the sequence for each <math>i</math>. Because <math>a_i > 0, a_{k_i} > a_{m-j+1}</math>.
+Combining all of our conditions we have that each of <math>k_i</math> must be distinct integers such that
+<cmath>m-j+1 < k_i \le m</cmath>
+However, there are <math>j</math> distinct <math>k_i</math>, but only <math>j-1</math> integers satisfying the above inequality, so we have a contradiction. Our assumption that <math>a_j + a_{m-j+1} \le n</math> was false, so <math>a_j + a_{m-j+1} \ge n+1</math> for all <math>j</math> such that <math>1 \le j \le m</math> Summing these inequalities together for <math>1 \le j \le m</math> gives
+<cmath> 2(a_1+a_2+ \dots a_m) \ge m(n+1) </cmath>
+which rearranges to
+<cmath> \frac{a_1+a_2+ \dots a_m}{m} \ge \frac{n+1}{2} </cmath>
+==See Also==
+{{IMO box|year=1994|before=First Question|num-a=2}}

1994 IMO (Problems) • Resources
Preceded by First Question	1 • 2 • 3 • 4 • 5 • 6	Followed by Problem 2
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Difference between revisions of "1994 IMO Problems/Problem 1"

Latest revision as of 00:28, 22 November 2023

Solution

See Also