Given a regular $n$-gon inscribed in a circle of radius 1, where $n > 3$. Define $G(n)$ as the average length of the diagonals of this $n$-gon. Prove that if $n \rightarrow \infty, G(n) \rightarrow \frac{4}{\pi}$.

Let $n$ be a positive integer and let $x_1,\dotsc,x_n$ be positive real numbers satisfying $\vert x_i-x_j\vert \le 1$ for all pairs $(i,j)$ with $1 \le i<j \le n$. Prove that \[\frac{x_1}{x_2}+\frac{x_2}{x_3}+\dots+\frac{x_{n-1}}{x_n}+\frac{x_n}{x_1} \ge \frac{x_2+1}{x_1+1}+\frac{x_3+1}{x_2+1}+\dots+\frac{x_n+1}{x_{n-1}+1}+\frac{x_1+1}{x_n+1}.\]

Positive real numbers $x,y$ satisfy $$\left \lfloor xy \right \rfloor - \lfloor x \rfloor \lfloor y \rfloor = 8.$$ Find the sum of all possible values of the quantity $\left \lfloor 2xy \right \rfloor - \lfloor 2x \rfloor \lfloor y \rfloor.$

In a football season, even number $n$ of teams plays a simple series, i.e. each team plays once against each other team. Show that ona can group the series into $n-1$ rounds such that in every round every team plays exactly one match.

For a given natural number $n$, two players randomly (uniformly distributed) select a common number $0 \le j \le n$, and then each of them independently randomly selects a subset of $\{1,2, \cdots, n \}$ with $j$ elements. Let $p_n$ be the probability that the same set was chosen. Prove that \[ \sum_{k=1}^{n} p_k = 2 \log{n} + 2 \gamma - 1 + o(1), \quad (n \to \infty),\] where $\gamma$ is the Euler constant.

Suppose one has an unlimited supply of identical tiles in the shape of a right triangle [asy] draw((0,0)--(3,0)--(3,2)--(0,0)); label("$A$",(0,0),SW); label("$B$",(3,0),SE); label("$C$",(3,2),NE); size(100); [/asy] such that, if we measure the sides $AB$ and $AC$ (in inches) their lengths are integers. Prove that one can pave a square completely (without overlaps) with a number of these tiles, exactly when $BC$ has integer length.

Determine all real polynomials $p$ such that $p(x+p(x))=x^2p(x)$ for all $x$.

Let \[ p(x) = a_nx^n + a_{n-1}x^{n-1} + \cdots + a_1x+a_0, \] where the coefficients $a_i$ are integers. If $p(0)$ and $p(1)$ are both odd, show that $p(x)$ has no integral roots.

$M$ is infinite set of natural numbers. If $a,b, a\neq b$ are in $M$, then $a^b+2$ or $a^b-2$ ( or both) are in $M$. Prove that there is composite number in $M$

A point is chosen at random within the square in the coordinate plane whose vertices are $(0, 0),$ $(2020, 0),$ $(2020, 2020),$ and $(0, 2020)$. The probability that the point is within $d$ units of a lattice point is $\tfrac{1}{2}$. (A point $(x, y)$ is a lattice point if $x$ and $y$ are both integers.) What is $d$ to the nearest tenth$?$ $\textbf{(A) } 0.3 \qquad \textbf{(B) } 0.4 \qquad \textbf{(C) } 0.5 \qquad \textbf{(D) } 0.6 \qquad \textbf{(E) } 0.7$

Say a number is [i]tico[/i] if the sum of it's digits is a multiple of $2003$. $\text{(i)}$ Show that there exists a positive integer $N$ such that the first $2003$ multiples, $N,2N,3N,\ldots 2003N$ are all tico. $\text{(ii)}$ Does there exist a positive integer $N$ such that all it's multiples are tico?

What is the greatest common factor of $12345678987654321$ and $12345654321$? [i]Proposed by Evan Chen[/i]

Find all positive integers $n$ such that $21$ divides $2^{2^n}+2^n+1$.

Let $C$ be a point on the extension of the diameter $AB$ of a circle. A line through $C$ is tangent to the circle at point $N$. The bisector of $\angle ACN$ meets the lines $AN$ and $BN$ at $P$ and $Q$ respectively. Prove that $PN = QN$.

For a point $ P $ situated in the plane determined by a triangle $ ABC, $ prove the following inequality: $$ BC\cdot PB\cdot PC+AC\cdot PC\cdot PA +AB\cdot PA\cdot PB\ge AB\cdot BC\cdot CA $$

Given a real number $\lambda > 1$, let $P$ be a point on the arc $BAC$ of the circumcircle of $\bigtriangleup ABC$. Extend $BP$ and $CP$ to $U$ and $V$ respectively such that $BU = \lambda BA$, $CV = \lambda CA$. Then extend $UV$ to $Q$ such that $UQ = \lambda UV$. Find the locus of point $Q$.

Let a.b.c be positive reals such that their sum is 1. Prove that $ \frac{a^{2}b^{2}}{c^{3}(a^{2}\minus{}ab\plus{}b^{2})}\plus{}\frac{b^{2}c^{2}}{a^{3}(b^{2}\minus{}bc\plus{}c^{2})}\plus{}\frac{a^{2}c^{2}}{b^{3}(a^{2}\minus{}ac\plus{}c^{2})}\geq \frac{3}{ab\plus{}bc\plus{}ac}$

In multiplying two positive integers $a$ and $b$, Ron reversed the digits of the two-digit number $a$. His errorneous product was $161$. What is the correct value of the product of $a$ and $b$? $ \textbf{(A)}\ 116 \qquad \textbf{(B)}\ 161 \qquad \textbf{(C)}\ 204 \qquad \textbf{(D)}\ 214 \qquad \textbf{(E)}\ 224 $

A regular tetrahedral massless frame whose side length is physically variable (with the constraint of the tetrahedron being regular) is dipped in a soap solution of surface tension $T$, taken outside and allowed to settle after a little wiggle.\\ The soap film is formed such that there is no volume in space that is enclosed by any of the surfaces soap film and all the soap film surfaces are planar. You may assume the configuration of the soap film without proof.\\ Now 4 point charges of charge $q$ are fixed at the vertices of the tetrahedron.\\ The system now sets into motion with the shape and nature of soap film being unaltered at all times.\\ [list] [*] Find the side length of the tetrahedron for which the system attains mechanical equilibrium. [/*] [*] Find the differential equation(s) governing the side length with respect to time.[/*] [*] If the amplitude of oscillations are very small, find the time period of oscillations.[/*] [/list]

Non-degenerate quadrilateral $ABCD$ with $AB = AD$ and $BC = CD$ has integer side lengths, and $\angle ABC = \angle BCD = \angle CDA$. If $AB = 3$ and $B \ne D$, how many possible lengths are there for $BC$?

Square $S$ is the unit square with vertices at $(0, 0)$, $(0, 1)$, $(1, 0)$ and $(1, 1)$. We choose a random point $(x, y)$ inside $S$ and construct a rectangle with length $x$ and width $y$. What is the average of $\lfloor p \rfloor$ where $p$ is the perimeter of the rectangle? $\lfloor x \rfloor$ is the greatest integer less than or equal to $x$.

Suppose from $(m+2)\times(n+2)$ rectangle we cut $4$, $1\times1$ corners. Now on first and last row first and last columns we write $2(m+n)$ real numbers. Prove we can fill the interior $m\times n$ rectangle with real numbers that every number is average of it's $4$ neighbors.

Let $N$ be the number of ordered triples $(A,B,C)$ of integers satisfying the conditions (a) $0\leq A<B<C\leq99$, (b) there exist integers $a$, $b$, and $c$, and prime $p$ where $0\leq b < a < c < p$, (c) $p$ divides $A-a$, $B-b$, and $C-c$, and (d) each ordered triple $(A,B,C)$ and each ordered triple $(b,a,c)$ form arithmetic sequences. Find $N$.

Let $n \ge 2$ and $ a_1, a_2, \ldots , a_n $, nonzero real numbers not necessarily distinct. We define matrix $A = (a_{ij})_{1 \le i,j \le n} \in M_n( \mathbb{R} )$ , $a_{i,j} = max \{ a_i, a_j \}$, $\forall i,j \in \{ 1,2 , \ldots , n \} $. Show that $\mathbf{rank}(A) $= $\mathbf{card} $ $\{ a_k | k = 1,2, \ldots n \} $

Find all values of $a$ such that absolute value of one of the roots of the equation $x^2 + (a - 2)x - 2a^2 + 5a - 3 = 0$ is twice of absolute value of the other root.