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Difference between revisions of "2017 USAMO Problems"

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===Problem 2===
 
===Problem 2===
 
Let <math>m_1, m_2, \ldots, m_n</math> be a collection of <math>n</math> positive integers, not necessarily distinct. For any sequence of integers <math>A = (a_1, \ldots, a_n)</math> and any permutation <math>w = w_1, \ldots, w_n</math> of <math>m_1, \ldots, m_n</math>, define an <math>A</math>-inversion of <math>w</math> to be a pair of entries <math>w_i, w_j</math> with <math>i < j</math> for which one of the following conditions holds:
 
Let <math>m_1, m_2, \ldots, m_n</math> be a collection of <math>n</math> positive integers, not necessarily distinct. For any sequence of integers <math>A = (a_1, \ldots, a_n)</math> and any permutation <math>w = w_1, \ldots, w_n</math> of <math>m_1, \ldots, m_n</math>, define an <math>A</math>-inversion of <math>w</math> to be a pair of entries <math>w_i, w_j</math> with <math>i < j</math> for which one of the following conditions holds:
<math>a_i \ge w_i > w_j</math>
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<cmath>a_i \ge w_i > w_j,</cmath>
<math>w_j > a_i \ge w_i</math>, or
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<cmath>w_j > a_i \ge w_i,</cmath> or
<math>w_i > w_j > a_i</math>.
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<cmath>w_i > w_j > a_i.</cmath>
 
Show that, for any two sequences of integers <math>A = (a_1, \ldots, a_n)</math> and <math>B = (b_1, \ldots, b_n)</math>, and for any positive integer <math>k</math>, the number of permutations of <math>m_1, \ldots, m_n</math> having exactly <math>k</math> <math>A</math>-inversions is equal to the number of permutations of <math>m_1, \ldots, m_n</math> having exactly <math>k</math> <math>B</math>-inversions.
 
Show that, for any two sequences of integers <math>A = (a_1, \ldots, a_n)</math> and <math>B = (b_1, \ldots, b_n)</math>, and for any positive integer <math>k</math>, the number of permutations of <math>m_1, \ldots, m_n</math> having exactly <math>k</math> <math>A</math>-inversions is equal to the number of permutations of <math>m_1, \ldots, m_n</math> having exactly <math>k</math> <math>B</math>-inversions.
  
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Let <math>P_1</math>, <math>P_2</math>, <math>\dots</math>, <math>P_{2n}</math> be <math>2n</math> distinct points on the unit circle <math>x^2+y^2=1</math>, other than <math>(1,0)</math>. Each point is colored either red or blue, with exactly <math>n</math> red points and <math>n</math> blue points. Let <math>R_1</math>, <math>R_2</math>, <math>\dots</math>, <math>R_n</math> be any ordering of the red points. Let <math>B_1</math> be the nearest blue point to <math>R_1</math> traveling counterclockwise around the circle starting from <math>R_1</math>. Then let <math>B_2</math> be the nearest of the remaining blue points to <math>R_2</math> travelling counterclockwise around the circle from <math>R_2</math>, and so on, until we have labeled all of the blue points <math>B_1, \dots, B_n</math>. Show that the number of counterclockwise arcs of the form <math>R_i \to B_i</math> that contain the point <math>(1,0)</math> is independent of the way we chose the ordering <math>R_1, \dots, R_n</math> of the red points.
 
Let <math>P_1</math>, <math>P_2</math>, <math>\dots</math>, <math>P_{2n}</math> be <math>2n</math> distinct points on the unit circle <math>x^2+y^2=1</math>, other than <math>(1,0)</math>. Each point is colored either red or blue, with exactly <math>n</math> red points and <math>n</math> blue points. Let <math>R_1</math>, <math>R_2</math>, <math>\dots</math>, <math>R_n</math> be any ordering of the red points. Let <math>B_1</math> be the nearest blue point to <math>R_1</math> traveling counterclockwise around the circle starting from <math>R_1</math>. Then let <math>B_2</math> be the nearest of the remaining blue points to <math>R_2</math> travelling counterclockwise around the circle from <math>R_2</math>, and so on, until we have labeled all of the blue points <math>B_1, \dots, B_n</math>. Show that the number of counterclockwise arcs of the form <math>R_i \to B_i</math> that contain the point <math>(1,0)</math> is independent of the way we chose the ordering <math>R_1, \dots, R_n</math> of the red points.
  
[[2017 USAMO Problems/Problem 4|Solution]]
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[[2017 USAJMO Problems/Problem 6|Solution]]
  
 
===Problem 5===
 
===Problem 5===
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{{MAA Notice}}
 
{{MAA Notice}}
  
{{USAMO newbox|year= 2017 |before=[[2016 USAMO]]|after=[[2018 USAMO]]}}
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{{USAMO newbox|year=2017|before=[[2016 USAMO Problems]]|after=[[2018 USAMO Problems]]}}

Latest revision as of 12:49, 22 November 2023

Day 1

Note: For any geometry problem whose statement begins with an asterisk ($*$), the first page of the solution must be a large, in-scale, clearly labeled diagram. Failure to meet this requirement will result in an automatic 1-point deduction.

Problem 1

Prove that there are infinitely many distinct pairs $(a,b)$ of relatively prime positive integers $a > 1$ and $b > 1$ such that $a^b + b^a$ is divisible by $a + b.$

Solution

Problem 2

Let $m_1, m_2, \ldots, m_n$ be a collection of $n$ positive integers, not necessarily distinct. For any sequence of integers $A = (a_1, \ldots, a_n)$ and any permutation $w = w_1, \ldots, w_n$ of $m_1, \ldots, m_n$, define an $A$-inversion of $w$ to be a pair of entries $w_i, w_j$ with $i < j$ for which one of the following conditions holds: \[a_i \ge w_i > w_j,\] \[w_j > a_i \ge w_i,\] or \[w_i > w_j > a_i.\] Show that, for any two sequences of integers $A = (a_1, \ldots, a_n)$ and $B = (b_1, \ldots, b_n)$, and for any positive integer $k$, the number of permutations of $m_1, \ldots, m_n$ having exactly $k$ $A$-inversions is equal to the number of permutations of $m_1, \ldots, m_n$ having exactly $k$ $B$-inversions.

Solution

Problem 3

($*$) Let $ABC$ be a scalene triangle with circumcircle $\Omega$ and incenter $I$. Ray $AI$ meets $\overline{BC}$ at $D$ and meets $\Omega$ again at $M$; the circle with diameter $\overline{DM}$ cuts $\Omega$ again at $K$. Lines $MK$ and $BC$ meet at $S$, and $N$ is the midpoint of $\overline{IS}$. The circumcircles of $\triangle KID$ and $\triangle MAN$ intersect at points $L_1$ and $L_2$. Prove that $\Omega$ passes through the midpoint of either $\overline{IL_1}$ or $\overline{IL_2}$.

Solution

Day 2

Note: For any geometry problem whose statement begins with an asterisk ($*$), the first page of the solution must be a large, in-scale, clearly labeled diagram. Failure to meet this requirement will result in an automatic 1-point deduction.

Problem 4

Let $P_1$, $P_2$, $\dots$, $P_{2n}$ be $2n$ distinct points on the unit circle $x^2+y^2=1$, other than $(1,0)$. Each point is colored either red or blue, with exactly $n$ red points and $n$ blue points. Let $R_1$, $R_2$, $\dots$, $R_n$ be any ordering of the red points. Let $B_1$ be the nearest blue point to $R_1$ traveling counterclockwise around the circle starting from $R_1$. Then let $B_2$ be the nearest of the remaining blue points to $R_2$ travelling counterclockwise around the circle from $R_2$, and so on, until we have labeled all of the blue points $B_1, \dots, B_n$. Show that the number of counterclockwise arcs of the form $R_i \to B_i$ that contain the point $(1,0)$ is independent of the way we chose the ordering $R_1, \dots, R_n$ of the red points.

Solution

Problem 5

Let $\mathbf{Z}$ denote the set of all integers. Find all real numbers $c > 0$ such that there exists a labeling of the lattice points $( x, y ) \in \mathbf{Z}^2$ with positive integers for which: only finitely many distinct labels occur, and for each label $i$, the distance between any two points labeled $i$ is at least $c^i$.

Solution

Problem 6

Find the minimum possible value of \[\frac{a}{b^3+4}+\frac{b}{c^3+4}+\frac{c}{d^3+4}+\frac{d}{a^3+4}\]given that $a$, $b$, $c$, $d$ are nonnegative real numbers such that $a+b+c+d=4$.

Solution

The problems on this page are copyrighted by the Mathematical Association of America's American Mathematics Competitions. AMC logo.png

2017 USAMO (ProblemsResources)
Preceded by
2016 USAMO Problems 		Followed by
2018 USAMO Problems
1 2 3 4 5 6
All USAMO Problems and Solutions
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