Problems
We say that a figure is convex if a segment connecting any two points
lays fully within the figure. On the picture below the pentagon on the
left is convex and the one on the right is not.
Is it possible to draw \(18\) points
inside a convex pentagon so that each of the ten triangles formed by its
sides and diagonals contains equal amount of points?
Cambria was various cuboids from \(1\times 1\times1\) cubes. She initially built one cuboid, then increased its length and width by \(1\) and reduced its height by \(2\). She noticed that she needed the same number of \(1\times 1\times 1\) cubes to build both the original and new cuboids. Show that the number of cubes used for each of the cuboids is divisible by \(3\).
Is it possible to cut an equilateral triangle into three equal hexagons?
A labyrinth was drawn on a \(5\times
5\) grid square with an outer wall and an exit one cell wide, as
well as with inner walls running along the grid lines. In the picture,
we have hidden all the inner walls from you (We give you several copies
to facilitate drawing) 
Please draw how the walls were arranged. Keep in mind that the numbers
in the cells represent the smallest number of steps needed to exit the
maze, starting from that cell. A step can be taken to any adjacent cell
vertically or horizontally, but not diagonally (and only if there is no
wall between them, of course).
Is it possible to cut this figure, called "camel"
a) along the grid lines;
b) not necessarily along the grid lines;
into \(3\) parts, which you can use
to build a square?
(We give you several copies to facilitate drawing)
Michael used different numbers \(\{0,1,2,3,4,5,6,7,8,9\}\) to put in the
circles in the picture below, without using any one of them twice.
Inside each triangle he wrote down either the sum or the product of the
numbers at its vertices. Then he erased the numbers in the circles.
Which numbers need to be written in circles so that the condition is
satisfied?
Solve the puzzle: \[\textrm{AC}\times\textrm{CC}\times\textrm{K} = 2002.\] Different letters correspond to different digits, identical letters correspond to identical digits.
The triangle \(ABC\) is equilateral.
The point \(K\) is chosen on the side
\(AB\) and points \(L\) and \(M\) are on the side \(BC\) in such a way that \(L\) lies on the segment \(BM\). We have the following properties:
\(KL = KM,\) \(BL = 2,\, AK = 3.\) Find the length of
\(CM\).
Long ago, in a galaxy far away, there was a planet of liars and truth-tellers. Liars always tell lies, and truth-tellers always tell the truth. All the people on the planet look exactly the same, so you can’t tell who is who just by looking at them. In this problem sheet, we will explore some clever ways we can gather information from these aliens despite this difficulty.
Last weekend we held the verbal challenge and today we decided to demonstrate solutions of the most juicy problems.