#CompetitionYearsProblemsYears
1International Mathematical Olympiad1959–2025398
2Middle European Mathematical Olympiad2009–2025160
International Mathematical Olympiad 2019 Problem 2

In triangle ABCABC, point A1A_1 lies on side BCBC and point B1B_1 lies on side ACAC. Let PP and QQ be points on segments AA1AA_1 and BB1BB_1, respectively, such that PQPQ is parallel to ABAB. Let P1P_1 be a point on line PB1PB_1, such that B1B_1 lies strictly between PP and P1P_1, and PP1C=BAC\angle PP_1C = \angle BAC. Similarly, let Q1Q_1 be a point on line QA1QA_1, such that A1A_1 lies strictly between QQ and Q1Q_1, and CQ1Q=CBA\angle CQ_1Q = \angle CBA.

Prove that points PP, QQ, P1P_1, and Q1Q_1 are concyclic.

International Mathematical Olympiad 2019 Problem 3

A social network has 2019 users, some pairs of whom are friends. Whenever user AA is friends with user BB, user BB is also friends with user AA. Events of the following kind may happen repeatedly, one at a time:

Three users AA, BB, and CC such that AA is friends with both BB and CC, but BB and CC are not friends, change their friendship statuses such that BB and CC are now friends, but AA is no longer friends with BB, and no longer friends with CC. All other friendship statuses are unchanged.

Initially, 1010 users have 1009 friends each, and 1009 users have 1010 friends each. Prove that there exists a sequence of such events after which each user is friends with at most one other user.

International Mathematical Olympiad 2019 Problem 5

The Bank of Bath issues coins with an HH on one side and a TT on the other. Harry has nn of these coins arranged in a line from left to right. He repeatedly performs the following operation: if there are exactly k>0k > 0 coins showing HH, then he turns over the kkth coin from the left; otherwise, all coins show TT and he stops. For example, if n=3n = 3 the process starting with the configuration THTTHT would be THTHHTHTTTTTTHT \to HHT \to HTT \to TTT, which stops after three operations.

(a) Show that, for each initial configuration, Harry stops after a finite number of operations.

(b) For each initial configuration CC, let L(C)L(C) be the number of operations before Harry stops. For example, L(THT)=3L(THT) = 3 and L(TTT)=0L(TTT) = 0. Determine the average value of L(C)L(C) over all 2n2^n possible initial configurations CC.

International Mathematical Olympiad 2019 Problem 6

Let II be the incentre of acute triangle ABCABC with ABACAB \neq AC. The incircle ω\omega of ABCABC is tangent to sides BCBC, CACA, and ABAB at DD, EE, and FF, respectively. The line through DD perpendicular to EFEF meets ω\omega again at RR. Line ARAR meets ω\omega again at PP. The circumcircles of triangles PCEPCE and PBFPBF meet again at QQ.

Prove that lines DIDI and PQPQ meet on the line through AA perpendicular to AIAI.

Middle European Mathematical Olympiad 2019 Problem I-2

Let n3n \geq 3 be an integer. We say that a vertex AiA_i (1in1 \leq i \leq n) of a convex polygon A1A2AnA_1A_2\ldots A_n is Bohemian if its reflection with respect to the midpoint of the segment Ai1Ai+1A_{i-1}A_{i+1} (with A0=AnA_0 = A_n and An+1=A1A_{n+1} = A_1) lies inside or on the boundary of the polygon A1A2AnA_1A_2\ldots A_n. Determine the smallest possible number of Bohemian vertices a convex nn-gon can have (depending on nn).

(A convex polygon A1A2AnA_1A_2\ldots A_n has nn vertices with all inner angles smaller than 180°180°.)

Middle European Mathematical Olympiad 2019 Problem I-3

Let ABCABC be an acute-angled triangle with AC>BCAC > BC and circumcircle ω\omega. Suppose that PP is a point on ω\omega such that AP=ACAP = AC and that PP is an interior point of the shorter arc BCBC of ω\omega. Let QQ be the point of intersection of the lines APAP and BCBC. Furthermore, suppose that RR is a point on ω\omega such that QA=QRQA = QR and that RR is an interior point of the shorter arc ACAC of ω\omega. Finally, let SS be the point of intersection of the line BCBC with the perpendicular bisector of the side ABAB. Prove that the points PP, QQ, RR, and SS are concyclic.

Middle European Mathematical Olympiad 2019 Problem T-1

Determine the smallest and the greatest possible values of the expression (1a2+1+1b2+1+1c2+1)(a2a2+1+b2b2+1+c2c2+1)\left(\frac{1}{a^2 + 1} + \frac{1}{b^2 + 1} + \frac{1}{c^2 + 1}\right)\left(\frac{a^2}{a^2 + 1} + \frac{b^2}{b^2 + 1} + \frac{c^2}{c^2 + 1}\right) provided aa, bb, and cc are non-negative real numbers satisfying ab+bc+ca=1ab + bc + ca = 1.

Middle European Mathematical Olympiad 2019 Problem T-3

There are nn boys and nn girls in a school class, where nn is a positive integer. The heights of all the children in this class are distinct. Every girl determines the number of boys that are taller than her, subtracts the number of girls that are taller than her, and writes the result on a piece of paper. Every boy determines the number of girls that are shorter than him, subtracts the number of boys that are shorter than him, and writes the result on a piece of paper. Prove that the numbers written down by the girls are the same as the numbers written down by the boys (up to a permutation).

Middle European Mathematical Olympiad 2019 Problem T-4

Prove that every integer from 11 to 20192019 can be represented as an arithmetic expression consisting of up to 1717 symbols 22 and an arbitrary number of additions, subtractions, multiplications, divisions and brackets. The 22's may not be used for any other operation, for example to form multi-digit numbers (such as 222222) or powers (such as 222^2).

Valid examples: ((2×2+2)×222)×2=22,(2×2×22)×(2×2+2+2+22)=42.\left((2 \times 2 + 2) \times 2 - \frac{2}{2}\right) \times 2 = 22, \quad (2 \times 2 \times 2 - 2) \times \left(2 \times 2 + \frac{2 + 2 + 2}{2}\right) = 42.

Middle European Mathematical Olympiad 2019 Problem T-5

Let ABCABC be an acute-angled triangle such that AB<ACAB < AC. Let DD be the point of intersection of the perpendicular bisector of the side BCBC with the side ACAC. Let PP be a point on the shorter arc ACAC of the circumcircle of the triangle ABCABC such that DPBCDP \parallel BC. Finally, let MM be the midpoint of the side ABAB. Prove that APD=MPB\angle APD = \angle MPB.

Middle European Mathematical Olympiad 2019 Problem T-8

Let NN be a positive integer such that the sum of the squares of all positive divisors of NN is equal to the product N(N+3)N(N + 3). Prove that there exist two indices ii and jj such that N=FiFjN = F_i \cdot F_j, where (Fn)n=1(F_n)_{n=1}^{\infty} is the Fibonacci sequence defined by F1=F2=1F_1 = F_2 = 1 and Fn=Fn1+Fn2F_n = F_{n-1} + F_{n-2} for all n3n \geq 3.