Let $C_1$ and $C_2$ be tangent circles internally at point $A$, with $C_2$ inside of $C_1$. Let $BC$ be a chord of $C_1$ that is tangent to $C_2$. Prove that the ratio between the length $BC$ and the perimeter of the triangle $ABC$ is constant, that is, it does not depend of the selection of the chord $BC$ that is chosen to construct the trangle.

Determine if there exists a positive integer $n$ such that $n^2+11$ is a prime number and $n+4$ is a perfect cube.

We have a table in the form of a regular polygon with $1000$ sides, where each side has length $1$. At one of the vertices is a beetle (consider this vertex to be fixed). The $1000$ vertices must be numbered, in some order, using the numbers $1, 2,\ldots ,1000$ such that the beetle is at vertex $1$. The beetle can only move along the edge of the table and always moves clockwise. The beetle moves from vertex $1$ to vertex $2$ and stops there. then it moves from vertex $2$ to vertex $3$, and stops there. So on, until the beetle ends its journey at vertex $1000$. Find the number of ways the numbers can be assigned to the vertices so that the total length of the beetle's journey is $2017$.

We have a set of 2n positive integers whose sum is a multiple of n. One operation consists of choosing n of them and adding the same positive integer to all of them. Show that, starting from the initial 2n numbers, we can get all are equal, performing a maximum of 2n - 1 operations.

Let $ABCD$ be a trapezoid of bases $AD$ and $BC$ , with $AD> BC$, whose diagonals are cut at point $E$. Let $P$ and $Q$ be the feet of the perpendicular drawn from $E$ on the sides $AD$ and $BC$, respectively, with $P$ and $Q$ in segments $AD$ and $BC,$ respectively. Let $I$ be the center of the triangle $AED$ and let $K$ be the point of intersection of the lines $AI$ and $CD$. If $AP + AE = BQ + BE$, show that $AI = IK$.

For each positive integer $k$, let $S(k)$ be the sum of the digits of $k$ in the decimal system. Prove that there exists a positive integer $k$, which does not have the digit $9$ in its decimal representation, such that: $$S(2^{24^{2017}}k)=S(k)$$