MathDB

2

Part of 2021 Middle European Mathematical Olympiad

Problems(2)

Bishop circuit

Source: 2021 MEMO I-2

9/5/2021
Let mm and nn be positive integers. Some squares of an m×nm \times n board are coloured red. A sequence a1,a2,,a2ra_1, a_2, \ldots , a_{2r} of 2r42r \ge 4 pairwise distinct red squares is called a bishop circuit if for every k{1,,2r}k \in \{1, \ldots , 2r \}, the squares aka_k and ak+1a_{k+1} lie on a diagonal, but the squares aka_k and ak+2a_{k+2} do not lie on a diagonal (here a2r+1=a1a_{2r+1}=a_1 and a2r+2=a2a_{2r+2}=a_2). In terms of mm and nn, determine the maximum possible number of red squares on an m×nm \times n board without a bishop circuit. (Remark. Two squares lie on a diagonal if the line passing through their centres intersects the sides of the board at an angle of 4545^\circ.)
combinatoricsChessboardgraph theory
Pretty Polynomials

Source: 2021 MEMO T-2

9/5/2021
Given a positive integer nn, we say that a polynomial PP with real coefficients is nn-pretty if the equation P(x)=P(x)P(\lfloor x \rfloor)=\lfloor P(x) \rfloor has exactly nn real solutions. Show that for each positive integer nn
[*] there exists an n-pretty polynomial; [*] any nn-pretty polynomial has a degree of at least 2n+13\tfrac{2n+1}{3}.
(Remark. For a real number xx, we denote by x\lfloor x \rfloor the largest integer smaller than or equal to xx.)
polynomialalgebrafloor functionmemoMEMO 2021