You are given $2024$ yellow and $2024$ blue points on the plane, and no three of the points are on the same line. We call a pair of nonnegative integers $(a, b)$ [i]good[/i] if there exists a half-plane with exactly $a$ yellow and $b$ blue points. Find the smallest possible number of good pairs. The points that lie on the line that is the boundary of the half-plane are considered to be outside the half-plane. [i]Proposed by Anton Trygub[/i]

The infinite product $$\sqrt[3]{10}\cdot\sqrt[3]{\sqrt[3]{10}}\cdot\sqrt[3]{\sqrt[3]{\sqrt[3]{10}}}\dots$$ evaluates to a real number. What is that number? $\textbf{(A) }\sqrt{10}\qquad\textbf{(B) }\sqrt[3]{100}\qquad\textbf{(C) }\sqrt[4]{1000}\qquad\textbf{(D) }10\qquad\textbf{(E) }10\sqrt[3]{10}$

Prove that for any positive integers $p,q$ such that $\sqrt{11}>\frac{p}{q}$, the following inequality holds: \[\sqrt{11}-\frac{p}{q}>\frac{1}{2pq}.\]

A cube of edge $2$ with one of the corner unit cubes removed is called a [i]piece[/i]. Prove that if a cube $T$ of edge $2^n$ is divided into $2^{3n}$ unit cubes and one of the unit cubes is removed, then the rest can be cut into [i]pieces[/i].

Find the smallest $x \in\mathbb{N}$ for which $\frac{7x^{25}-10}{83}$ is an integer.

There are 50 slips of paper numbered from 1 to 50. It is desired to pick 3 slips such that for any of the three numbers, divided by the greatest common divisor of the other two, the square root of the result is a rational number. How many unordered triples of slips satisfy this condition?

Find the largest integer $A$ such that, for any permutation of the natural numbers not exceeding $100$, the sum of some ten successive numbers is at least $A$.

Find all functions $~$ $f: \mathbb{R} \to \mathbb{R}$ $~$ which satisfy the equation \[ f(x+yf(x))\, =\, f(f(x)) + xf(y)\, . \]

(A.Myakishev) Let triangle $ A_1B_1C_1$ be symmetric to $ ABC$ wrt the incenter of its medial triangle. Prove that the orthocenter of $ A_1B_1C_1$ coincides with the circumcenter of the triangle formed by the excenters of $ ABC$.

Find all positive integers $n$ satisfying $2n+7 \mid n! -1$.

Let $A_1,A_2,\cdots , A_n$ be arithmetic progressions of integers, each of $k$ terms, such that any two of these arithmetic progressions have at least two common elements. Suppose $b$ of these arithmetic progressions have common difference $d_1$ and the remaining arithmetic progressions have common difference $d_2$ where $0<b<n$. Prove that \[b \le 2\left(k-\frac{d_2}{gcd(d_1,d_2)}\right)-1.\]

Let T be a finite tree graph that has more than one vertex. Let s be the largest number of vertices of a subtree $X \subset T$ for which every vertex of X has a neighbor other than X. Let t be the smallest positive integer for which each edge of T is contained in exactly t stars, and each vertex of T is contained in at most 2t - 1 stars. (That is, the stars can be represented by multiplicity.) Prove that s = t. Note: a star of T is a vertex with degree $\geq$ 3 , including its neighouring edges and vertices.

If the function $f$ satisfies the equation $f(x) + f\left ( \dfrac{1}{\sqrt[3]{1-x^3}}\right ) = x^3$ for every real $x \neq 1$, what is $f(-1)$? $ \textbf{(A)}\ -1 \qquad\textbf{(B)}\ \dfrac 14 \qquad\textbf{(C)}\ \dfrac 12 \qquad\textbf{(D)}\ \dfrac 74 \qquad\textbf{(E)}\ \text{None of above} $

Find all positive real numbers $\lambda$ such that for all integers $n\geq 2$ and all positive real numbers $a_1,a_2,\cdots,a_n$ with $a_1+a_2+\cdots+a_n=n$, the following inequality holds: $\sum_{i=1}^n\frac{1}{a_i}-\lambda\prod_{i=1}^{n}\frac{1}{a_i}\leq n-\lambda$.

Three grasshoppers $A$, $B$ and $C$ are placed on a line. Grasshopper $B$ sits at the midpoint between $A$ and $C$. Every second, one of the grasshoppers jumps over one of the others to the symmetrical point on the other side (if $X$ jumps over $Y$ to point $X'$, then $XY $= $YX'$). After several jumps it so happened that they returned to the three initial points (but maybe in different order). Prove that in this case $B$ returns to his initial middle position. (AK Kovaldzhy)

Some distinct positive integers were written on a blackboard such that the sum of any two integers is a power of $2$. What is the maximal possible number written on the blackboard?

If the sides of a triangle have lengths $ a, b, c$, such that $ a \plus{} b \minus{} c \equal{} 2$, and $ 2ab \minus{} c^{2} \equal{} 4$, prove that the triangle is equilateral.

Let be a natural number $ n\ge 2, n $ real numbers $ b_1,b_2,\ldots ,b_n , $ and $ n-1 $ positive real numbers $ a_1,a_2,\ldots ,a_{n-1} $ such that $ a_1+a_2+\cdots +a_{n-1} =1. $ Prove the inequality $$ b_1^2+\frac{b_2^2}{a_1} +\frac{b_3^2}{a_2} +\cdots +\frac{b_n^2}{a_{n-1}} \ge 2b_1\left( b_2+b_3+\cdots +b_n \right) , $$ and specify when equality is attained. [i]Dumitru Acu[/i]

A line $l$ intersects the segment $AB$ perpendicular to $C$. Three circles are drawn successively with $AB, AC$ and $BC$ as the diameter. The largest circle intersects $l$ in $D$. The segments $DA$ and $DB$ still intersect the two smaller circles in $E$ and $F$. a. Prove that quadrilateral $CFDE$ is a rectangle. b. Prove that the line through $E$ and $F$ touches the circles with diameters $AC$ and $BC$ in $E$ and $F$. [asy] unitsize (2.5 cm); pair A, B, C, D, E, F, O; O = (0,0); A = (-1,0); B = (1,0); C = (-0.3,0); D = intersectionpoint(C--(C + (0,1)), Circle(O,1)); E = (C + reflect(A,D)*(C))/2; F = (C + reflect(B,D)*(C))/2; draw(Circle(O,1)); draw(Circle((A + C)/2, abs(A - C)/2)); draw(Circle((B + C)/2, abs(B - C)/2)); draw(A--B); draw(interp(C,D,-0.4)--D); draw(A--D--B); dot("$A$", A, W); dot("$B$", B, dir(0)); dot("$C$", C, SE); dot("$D$", D, NW); dot("$E$", E, SE); dot("$F$", F, SW); [/asy]

Find all real triples $(a,b,c)$ satisfying \[(2^{2a}+1)(2^{2b}+2)(2^{2c}+8)=2^{a+b+c+5}.\]

Prove that if $m,n$ are relatively prime positive integers, $x^m-y^n$ is irreducible in the complex numbers. (A polynomial $P(x,y)$ is irreducible if there do not exist nonconstant polynomials $f(x,y)$ and $g(x,y)$ such that $P(x,y) = f(x,y)g(x,y)$ for all $x,y$.) [i]David Yang.[/i]

Two circles $\omega_1$ and $\omega_2$ with equal radius intersect at two points $E$ and $X$. Arbitrary points $C, D$ lie on $\omega_1, \omega_2$. Parallel lines to $XC, XD$ from $E$ intersect $\omega_2, \omega_1$ at $A, B$, respectively. Suppose that $CD$ intersect $\omega_1, \omega_2$ again at $P, Q$, respectively. Prove that $ABPQ$ is cyclic. [i]Proposed by Ali Zamani[/i]

In acute triangle $ABC$ angle $B$ is greater than$C$. Let $M$ is midpoint of $BC$. $D$ and $E$ are the feet of the altitude from $C$ and $B$ respectively. $K$ and $L$ are midpoint of $ME$ and $MD$ respectively. If $KL$ intersect the line through $A$ parallel to $BC$ in $T$, prove that $TA=TM$.

The Fibonacci sequence $\{F_n\}$ is defined by $F_1 = F_2 = 1$ and $F_{n+2} = F_{n+1} + F_n$ for all positive integers $n$. Determine all triplets of positive integers $(k,m,n)$ such that $F_n = F_m^k$.

Let $ABC$ be an acute-angled triangle with $|AB| \neq |AC|$. Let $D$ be the foot of the altitude from $A$ to $BC$, and let $E$ be the intersection of the bisector of angle $\angle BAC$ with side $BC$. Let $P$ and $Q$ be the intersection points of the circumcircle of triangle $ADE$ with $AC$ and $AB$, respectively. Prove that the lines $AD$, $BP$, and $CQ$ pass through a common point.