Real numbers are given. For each () define
and let
(a) Prove that, for any real numbers ,
(b) Show that there are real numbers such that equality holds in .
| # | Competition | Years | Problems | Years |
|---|---|---|---|---|
| 1 | International Mathematical Olympiad | 1959–2025 | 398 | |
| 2 | Middle European Mathematical Olympiad | 2009–2025 | 160 |
Real numbers are given. For each () define
and let
(a) Prove that, for any real numbers ,
(b) Show that there are real numbers such that equality holds in .
Consider five points and such that is a parallelogram and is a cyclic quadrilateral. Let be a line passing through . Suppose that intersects the interior of the segment at and intersects line at . Suppose also that . Prove that is the bisector of angle .
In a mathematical competition some competitors are friends. Friendship is always mutual. Call a group of competitors a clique if each two of them are friends. (In particular, any group of fewer than two competitors is a clique.) The number of members of a clique is called its size.
Given that, in this competition, the largest size of a clique is even, prove that the competitors can be arranged in two rooms such that the largest size of a clique contained in one room is the same as the largest size of a clique contained in the other room.
In triangle the bisector of angle intersects the circumcircle again at , the perpendicular bisector of at , and the perpendicular bisector of at . The midpoint of is and the midpoint of is . Prove that the triangles and have the same area.
Let and be positive integers. Show that if divides , then .
Let be a positive integer. Consider
as a set of points in three-dimensional space. Determine the smallest possible number of planes, the union of which contains but does not include .