Difference between revisions of "1986 AIME Problems/Problem 12"

Revision as of 12:33, 25 November 2016

Problem

Let the sum of a set of numbers be the sum of its elements. Let $S$ be a set of positive integers, none greater than 15. Suppose no two disjoint subsets of $S$ have the same sum. What is the largest sum a set $S$ with these properties can have?

Solution

The maximum is $\boxed{061}$ , attained when $S=\{ 15,14,13,11,8\}$ . We must now prove that no such set has sum greater than 61. Suppose such a set $S$ existed. Then $S$ must have more than 4 elements, otherwise its sum would be at most $15+14+13+12=54$ .

$S$ can't have more than 5 elements. To see why, note that at least $1 + 6 + \dbinom{6}{2} + \dbinom{6}{3} + \dbinom{6}{4}=57$ of its subsets have at most four elements (the number of subsets with no elements plus the number of subsets with one element and so on), and each of them have sum at most 54. By the Pigeonhole Principle, two of these subsets would have the same sum.

Thus, $S$ would have to have 5 elements. $S$ contains both 15 and 14 (otherwise its sum is at most $10+11+12+13+15=61$ ). It follows that $S$ cannot contain both $a$ and $a-1$ for any $a\leq 13$ , or the subsets $\{a,14\}$ and $\{a-1,15\}$ would have the same sum. So now $S$ must contain 13 (otherwise its sum is at most $15+14+12+10+8=59$ ), and $S$ cannot contain 12, or the subsets $\{12,15\}$ and $\{13,14\}$ would have the same sum.

Now the only way $S$ could have sum at least $62=15+14+13+11+9$ would be if $S=\{ 15,14,13,11,9\}$ . But the subsets $\{9,15\}$ and $\{11,13\}$ have the same sum, so this set does not work. Therefore no $S$ with sum greater than 61 is possible and 61 is indeed the maximum.

Revision as of 16:37, 22 July 2015 (view source) Equationcrunchor (talk \| contribs) m (→‎Solution: removed some redundancy) ← Older edit		Revision as of 12:33, 25 November 2016 (view source) FlamezofDeath (talk \| contribs) m (→‎Solution) Newer edit →
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	The maximum is <math>\boxed{061}</math>, attained when <math>S=\{ 15,14,13,11,8\}</math>. We must now prove that no such set has sum greater than 61. Suppose such a set <math>S</math> existed. Then <math>S</math> must have more than 4 elements, otherwise its sum would be at most <math>15+14+13+12=54</math>.		The maximum is <math>\boxed{061}</math>, attained when <math>S=\{ 15,14,13,11,8\}</math>. We must now prove that no such set has sum greater than 61. Suppose such a set <math>S</math> existed. Then <math>S</math> must have more than 4 elements, otherwise its sum would be at most <math>15+14+13+12=54</math>.

−	<math>S</math> can't have at more than 5 elements. To see why, note that at least <math>1 + 6 + \dbinom{6}{2} + \dbinom{6}{3} + \dbinom{6}{4}=57</math> of its subsets have at most four elements (the number of subsets with no elements plus the number of subsets with one element and so on), and each of them have sum at most 54. By the Pigeonhole Principle, two of these subsets would have the same sum.	+	<math>S</math> can't have more than 5 elements. To see why, note that at least <math>1 + 6 + \dbinom{6}{2} + \dbinom{6}{3} + \dbinom{6}{4}=57</math> of its subsets have at most four elements (the number of subsets with no elements plus the number of subsets with one element and so on), and each of them have sum at most 54. By the Pigeonhole Principle, two of these subsets would have the same sum.

1986 AIME (Problems • Answer Key • Resources)
Preceded by Problem 11	Followed by Problem 13
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Difference between revisions of "1986 AIME Problems/Problem 12"

Revision as of 12:33, 25 November 2016

Problem

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