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Difference between revisions of "2005 USAMO Problems"

 
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Problems from the [[2005 USAMO | 2005]] [[USAMO]].
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= Day 1 =
 
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== Problem 1 ==
== Day 1 ==
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(''Zuming Feng'') Determine all composite positive integers <math>n</math> for which it is possible to arrange all divisors of <math>n</math> that are greater than 1 in a circle so that no two adjacent divisors are relatively prime.
 
 
=== Problem 1 ===
 
 
 
Determine all composite positive integers <math> \displaystyle n</math> for which it is possible to arrange all divisors of <math>n</math> that are greater than 1 in a circle so that no two adjacent divisors are relatively prime.
 
  
 
[[2005 USAMO Problems/Problem 1 | Solution]]
 
[[2005 USAMO Problems/Problem 1 | Solution]]
  
=== Problem 2 ===
+
== Problem 2 ==
 
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(''Răzvan Gelca'') Prove that the
Prove that the
 
 
system
 
system
<center>
+
<cmath>
<math>
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\begin{align*}
\begin{matrix} \qquad x^6+x^3+x^3y+y & = 147^{157} \\[.1in]
+
x^6+x^3+x^3y+y & = 147^{157} \\
 
x^3+x^3y+y^2+y+z^9 & = 157^{147}
 
x^3+x^3y+y^2+y+z^9 & = 157^{147}
\end{matrix}
+
\end{align*}
</math>
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</cmath>
</center>
+
has no solutions in integers <math>x</math>, <math>y</math>, and <math>z</math>.
has no solutions in integers <math> \displaystyle x </math>, <math> \displaystyle y </math>, and <math> \displaystyle z </math>.
 
  
=== Problem 3 ===
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[[2005 USAMO Problems/Problem 2 | Solution]]
  
Let <math> \displaystyle ABC </math> be an acute-angled triangle, and let <math> \displaystyle P </math> and <math> \displaystyle Q </math> be two points on side <math> \displaystyle BC </math>. Construct point <math> \displaystyle C_1 </math> in such a way that convex quadrilateral <math> \displaystyle APBC_1 </math> is cyclic, <math> \displaystyle QC_1 \mid\mid CA </math>, and <math> \displaystyle C_1 </math> and <math> \displaystyle Q </math> lie on opposite sides of line <math> \displaystyle AB </math>. Construct point <math> \displaystyle B_1 </math> in such a way that convex quadrilateral <math> \displaystyle APCB_1 </math> is cyclic, <math> \displaystyle QB_1 \mid\mid BA </math>, and <math> \displaystyle B_1 </math> and <math> \displaystyle Q </math>  lie on opposite sides of line <math> \displaystyle AC </math>.  Prove that points <math> \displaystyle B_1, C_1,P </math>, and <math> \displaystyle Q </math> lie on a circle.
+
== Problem 3 ==
 +
(''Zuming Feng'') Let <math>ABC</math> be an acute-angled triangle, and let <math>P</math> and <math>Q</math> be two points on side <math>BC</math>. Construct point <math>C_1 </math> in such a way that convex quadrilateral <math>APBC_1</math> is cyclic, <math>QC_1 \parallel CA</math>, and <math>C_1</math> and <math>Q</math> lie on opposite sides of line <math>AB</math>. Construct point <math>B_1</math> in such a way that convex quadrilateral <math>APCB_1</math> is cyclic, <math>QB_1 \parallel BA </math>, and <math>B_1 </math> and <math>Q </math>  lie on opposite sides of line <math>AC</math>.  Prove that points <math>B_1, C_1,P</math>, and <math>Q</math> lie on a circle.
  
== Day 2 ==
+
[[2005 USAMO Problems/Problem 3 | Solution]]
  
=== Problem 4 ===
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= Day 2 =
 +
== Problem 4 ==
 +
Legs <math>L_1,L_2,L_3,L_4</math> of a square table each have length <math>n</math>, where <math>n</math> is a positive integer. For how many ordered 4-tuples <math>\left(k_1,k_2,k_3,k_4\right)</math> of nonnegative integers can we cut a piece of length <math>k_i</math> from the end of leg <math>L_i\ (i=1,2,3,4)</math> and still have a stable table?
 +
 
 +
(The table is stable if it can be placed so that all four of the leg ends touch the floor. Note that a cut leg of length 0 is permitted.)
  
 
[[2005 USAMO Problems/Problem 4 | Solution]]
 
[[2005 USAMO Problems/Problem 4 | Solution]]
  
=== Problem 5 ===
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== Problem 5 ==
 +
Let <math>n</math> be an integer greater than 1. Suppose <math>2n</math> points are given in the plane, no three of which are collinear. Suppose <math>n</math> of the given <math>2n</math> points are colored blue and the other <math>n</math> colored red. A line in the plane is called a ''balancing line'' if it passes through one blue and one red point and, for each side of the line, the number of blue points on that side is equal to the number of red points on the same side.
 +
 
 +
Prove that there exist at least two balancing lines.
  
 
[[2005 USAMO Problems/Problem 5 | Solution]]
 
[[2005 USAMO Problems/Problem 5 | Solution]]
  
=== Problem 6 ===
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== Problem 6 ==
 +
For <math>m</math> a positive integer, let <math>s(m)</math> be the sum of the digits of <math>m</math>. For <math>n\ge 2</math>, let <math>f(n)</math> be the minimal <math>k</math> for which there  exists a set <math>S</math> of <math>n</math> positive integers such that  <math>s\left(\sum_{x\in X} x\right) = k</math> for any nonempty subset <math>X\subset S</math>.  Prove that there are constants <math>0 < C_1 < C_2</math> with
 +
<cmath>
 +
C_1 \log_{10} n \le f(n) \le C_2 \log_{10} n.
 +
</cmath>
  
 
[[2005 USAMO Problems/Problem 6 | Solution]]
 
[[2005 USAMO Problems/Problem 6 | Solution]]
  
== Resources ==
+
= Resources =
 
+
* [http://www.unl.edu/amc/e-exams/e8-usamo/e8-1-usamoarchive/2005-ua/questions/Day1/05USAMOday1.pdf 2005 USAMO Day 1 Problems]
* [[USAMO Problems and Solutions]]
+
* [http://www.unl.edu/amc/e-exams/e8-usamo/e8-1-usamoarchive/2005-ua/questions/Day2/05USAMOday2.pdf 2005 USAMO Day 2 Problems]
* [http://www.unl.edu/amc/e-exams/e8-usamo/e8-1-usamoarchive/2006-ua/2006usamoQ.pdf 2005 USAMO Problems]
+
* [http://www.unl.edu/amc/e-exams/e8-usamo/e8-1-usamoarchive/2005-ua/Solutions/05SOL.pdf 2005 USAMO Solutions]
* [http://www.unl.edu/amc/e-exams/e8-usamo/e8-1-usamoarchive/2006-ua/2006usamoS.pdf 2005 USAMO Solutions]
 
 
* [http://www.artofproblemsolving.com/Forum/resources.php?c=182&cid=27&year=2005 USAMO Problems on the Resources page]
 
* [http://www.artofproblemsolving.com/Forum/resources.php?c=182&cid=27&year=2005 USAMO Problems on the Resources page]
 +
{{USAMO newbox|year=2005|before=[[2004 USAMO]]|after=[[2006 USAMO]]}}
 +
{{MAA Notice}}

Latest revision as of 09:24, 14 May 2021

Day 1

Problem 1

(Zuming Feng) Determine all composite positive integers $n$ for which it is possible to arrange all divisors of $n$ that are greater than 1 in a circle so that no two adjacent divisors are relatively prime.

Solution

Problem 2

(Răzvan Gelca) Prove that the system \begin{align*} x^6+x^3+x^3y+y & = 147^{157} \\ x^3+x^3y+y^2+y+z^9 & = 157^{147} \end{align*} has no solutions in integers $x$, $y$, and $z$.

Solution

Problem 3

(Zuming Feng) Let $ABC$ be an acute-angled triangle, and let $P$ and $Q$ be two points on side $BC$. Construct point $C_1$ in such a way that convex quadrilateral $APBC_1$ is cyclic, $QC_1 \parallel CA$, and $C_1$ and $Q$ lie on opposite sides of line $AB$. Construct point $B_1$ in such a way that convex quadrilateral $APCB_1$ is cyclic, $QB_1 \parallel BA$, and $B_1$ and $Q$ lie on opposite sides of line $AC$. Prove that points $B_1, C_1,P$, and $Q$ lie on a circle.

Solution

Day 2

Problem 4

Legs $L_1,L_2,L_3,L_4$ of a square table each have length $n$, where $n$ is a positive integer. For how many ordered 4-tuples $\left(k_1,k_2,k_3,k_4\right)$ of nonnegative integers can we cut a piece of length $k_i$ from the end of leg $L_i\ (i=1,2,3,4)$ and still have a stable table?

(The table is stable if it can be placed so that all four of the leg ends touch the floor. Note that a cut leg of length 0 is permitted.)

Solution

Problem 5

Let $n$ be an integer greater than 1. Suppose $2n$ points are given in the plane, no three of which are collinear. Suppose $n$ of the given $2n$ points are colored blue and the other $n$ colored red. A line in the plane is called a balancing line if it passes through one blue and one red point and, for each side of the line, the number of blue points on that side is equal to the number of red points on the same side.

Prove that there exist at least two balancing lines.

Solution

Problem 6

For $m$ a positive integer, let $s(m)$ be the sum of the digits of $m$. For $n\ge 2$, let $f(n)$ be the minimal $k$ for which there exists a set $S$ of $n$ positive integers such that $s\left(\sum_{x\in X} x\right) = k$ for any nonempty subset $X\subset S$. Prove that there are constants $0 < C_1 < C_2$ with \[C_1 \log_{10} n \le f(n) \le C_2 \log_{10} n.\]

Solution

Resources

2005 USAMO (ProblemsResources)
Preceded by
2004 USAMO 		Followed by
2006 USAMO
1 2 3 4 5 6
All USAMO Problems and Solutions

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