57 lines
2.2 KiB
TeX
Executable File
57 lines
2.2 KiB
TeX
Executable File
\section{Extra Problems}
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\problem{USAMO 1996 Problem 6}
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Determine (with proof) whether there is a subset $X$ of
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the nonnegative integers with the following property: for any nonnegative integer $n$ there is exactly
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one solution of $a + 2b = n$ with $a, b \in X$.
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(The original USAMO question asked about all integers, not just nonnegative - this is harder,
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but still approachable with generating functions.)
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\vfill
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\problem{IMO Shortlist 1998}
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Let $a_0, a_1, ...$ be an increasing sequence of nonnegative integers
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such that every nonnegative integer can be
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expressed uniquely in the form $a_i + 2a_j + 4a_k$,
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where $i, j, k$ are not necessarily distinct.
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Determine $a_1998$.
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\vfill
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\problem{USAMO 1986 Problem 5}
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By a partition $\pi$ of an integer $n \geq 1$, we mean here a
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representation of $n$ as a sum of one or more positive integers where the summands must be put in
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nondecreasing order. (e.g., if $n = 4$, then the partitions $\pi$ are
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$1 + 1 + 1 + 1$, $1 + 1 + 2$, $1 + 3, 2 + 2$, and $4$).
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For any partition $\pi$, define $A(\pi)$ to be the number of ones which appear in $\pi$, and define $B(\pi)$
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to be the number of distinct integers which appear in $\pi$ (e.g, if $n = 13$ and $\pi$ is the partition
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$1 + 1 + 2 + 2 + 2 + 5$, then $A(\pi) = 2$ and $B(\pi) = 3$).
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Show that for any fixed $n$, the sum of $A(\pi)$ over all partitions of $\pi$ of $n$ is equal to the sum of
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$B(\pi)$ over all partitions of $\pi$ of $n$.
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\vfill
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\problem{USAMO 2017 Problem 2}
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Let $m_1, m_2, ..., m_n$ be a collection of $n$ distinct positive
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integers. For any sequence of integers $A = (a_1, ..., a_n)$ and any permutation $w = w_1, ..., w_n$ of
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$m_1, ..., m_n$, define an $A$-inversion of $w$ to be a pair of entries $w_i, w_j$ with $i < j$ for which one of the
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following conditions holds:
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\begin{itemize}
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\item $ai \geq wi > wj$
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\item $wj > ai \geq wi$
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\item $wi > wj > ai$
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\end{itemize}
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Show that for any two sequences of integers $A = (a_1, ..., a_n)$ and $B = (b_1, ..., b_n)$ and for any
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positive integer $k$, the number of permutations of $m_1, ..., m_n$ having exactly $k$ $A$-inversions is equal
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to the number of permutations of $m_1, ..., m_n$ having exactly $k$ $B$-inversions.
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(The original USAMO problem allowed the numbers $m_1, ..., m_n$ to not necessarily be distinct.)
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\vfill |