Overview

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Documents

YearFilenameLanguageSource
2025IMO-2025-problems-eng.pdfen
2024IMO-2024-problems-eng.pdfen
2023IMO-2023-problems-eng.pdfen
2022IMO-2022-problems-eng.pdfen
2021IMO-2021-problems-eng.pdfen
2020IMO-2020-problems-eng.pdfen
2019IMO-2019-problems-eng.pdfen
2018IMO-2018-problems-eng.pdfen
2017IMO-2017-problems-eng.pdfen
2016IMO-2016-problems-eng.pdfen
2015IMO-2015-problems-eng.pdfenglish
2014IMO-2014-problems-eng.pdfenglish
2013IMO-2013-problems-eng.pdfen
2012IMO-2012-problems-eng.pdfen
2011IMO-2011-problems-eng.pdfen
2010IMO-2010-problems-eng.pdfen
2009IMO-2009-problems-eng.pdfen
2008IMO-2008-problems-eng.pdfen
2007IMO-2007-problems-eng.pdfen
2006IMO-2006-problems-eng.pdfen
2005IMO-2005-problems-eng.pdfen
2004IMO-2004-problems-eng.pdfen
2003IMO-2003-problems-eng.pdfen
2002IMO-2002-problems-eng.pdfen
2001IMO-2001-problems-eng.pdfen
2000IMO-2000-problems-eng.pdfen
1999IMO-1999-problems-eng.pdfen
1998IMO-1998-problems-eng.pdfen
1997IMO-1997-problems-eng.pdfen
1996IMO-1996-problems-eng.pdfen
1995IMO-1995-problems-eng.pdfen
1994IMO-1994-problems-eng.pdfen
1993IMO-1993-problems-eng.pdfen
1992IMO-1992-problems-eng.pdfen
1991IMO-1991-problems-eng.pdfen
1990IMO-1990-problems-eng.pdfen
1989IMO-1989-problems-eng.pdfen
1988IMO-1988-problems-eng.pdfen
1987IMO-1987-problems-eng.pdfen
1986IMO-1986-problems-eng.pdfen
1985IMO-1985-problems-eng.pdfen
1984IMO-1984-problems-eng.pdfen
1983IMO-1983-problems-eng.pdfen
1982IMO-1982-problems-eng.pdfen
1981IMO-1981-problems-eng.pdfen
1979IMO-1979-problems-eng.pdfen
1978IMO-1978-problems-eng.pdfen
1977IMO-1977-problems-eng.pdfen
1976IMO-1976-problems-eng.pdfen
1975IMO-1975-problems-eng.pdfen
1974IMO-1974-problems-eng.pdfen
1973IMO-1973-problems-eng.pdfen
1972IMO-1972-problems-eng.pdfen
1971IMO-1971-problems-eng.pdfen
1970IMO-1970-problems-eng.pdfen
1969IMO-1969-problems-eng.pdfen
1968IMO-1968-problems-eng.pdfen
1967IMO-1967-problems-eng.pdfen
1966IMO-1966-problems-eng.pdfen
1965IMO-1965-problems-eng.pdfen
1964IMO-1964-problems-eng.pdfen
1963IMO-1963-problems-eng.pdfen
1962IMO-1962-problems-eng.pdfen
1961IMO-1961-problems-eng.pdfen
1960IMO-1960-problems-eng.pdfen
1959IMO-1959-problems-eng.pdfen

Problems

1966

International Mathematical Olympiad 1966 Problem 4

Prove that for every natural number nn, and for every real number xkπ/2tx \neq k\pi / 2^t (t=0,1,,n;kt = 0,1,\dots,n; k any integer) 1sin2x+1sin4x++1sin2nx=cotxcot2nx.\frac{1}{\sin 2x} + \frac{1}{\sin 4x} + \cdots + \frac{1}{\sin 2^n x} = \cot x - \cot 2^n x.

International Mathematical Olympiad 1966 Problem 5

Solve the system of equations a1a2x2+a1a3x3+a1a4x4=1a2a1x1+a2a3x3+a2a3x3=1a3a1x1+a3a2x2=1a4a1x1+a4a2x2+a4a3x3=1\begin{aligned} &|a_1 - a_2| x_2 & +\, |a_1 - a_3| x_3 & + |a_1 - a_4| x_4 &= 1 \\ |a_2 - a_1| x_1 & & +\, |a_2 - a_3| x_3 & + |a_2 - a_3| x_3 &= 1 \\ |a_3 - a_1| x_1 & + |a_3 - a_2| x_2 & & &= 1 \\ |a_4 - a_1| x_1 & + |a_4 - a_2| x_2 & +\, |a_4 - a_3| x_3 & &= 1 \end{aligned} where a1,a2,a3,a4a_1, a_2, a_3, a_4 are four different real numbers.

1965

International Mathematical Olympiad 1965 Problem 2

Consider the system of equations a11x1+a12x2+a13x3=0a_{11}x_1 + a_{12}x_2 + a_{13}x_3 = 0 a21x1+a22x2+a23x3=0a_{21}x_1 + a_{22}x_2 + a_{23}x_3 = 0 a31x1+a32x2+a33x3=0a_{31}x_1 + a_{32}x_2 + a_{33}x_3 = 0

with unknowns x1,x2,x3x_1, x_2, x_3. The coefficients satisfy the conditions:

(a) a11,a22,a33a_{11}, a_{22}, a_{33} are positive numbers;

(b) the remaining coefficients are negative numbers;

(c) in each equation, the sum of the coefficients is positive.

Prove that the given system has only the solution x1=x2=x3=0x_1 = x_2 = x_3 = 0.

International Mathematical Olympiad 1965 Problem 3

Given the tetrahedron ABCDABCD whose edges ABAB and CDCD have lengths aa and bb respectively. The distance between the skew lines ABAB and CDCD is dd, and the angle between them is ω\omega. Tetrahedron ABCDABCD is divided into two solids by plane ε\varepsilon, parallel to lines ABAB and CDCD. The ratio of the distances of ε\varepsilon from ABAB and CDCD is equal to kk. Compute the ratio of the volumes of the two solids obtained.

International Mathematical Olympiad 1965 Problem 5

Consider OAB\triangle OAB with acute angle AOBAOB. Through a point MOM \neq O perpendiculars are drawn to OAOA and OBOB, the feet of which are PP and QQ respectively. The point of intersection of the altitudes of OPQ\triangle OPQ is HH. What is the locus of HH if MM is permitted to range over (a) the side ABAB, (b) the interior of OAB\triangle OAB?

International Mathematical Olympiad 1965 Problem 6

In a plane a set of nn points (n3n \geq 3) is given. Each pair of points is connected by a segment. Let dd be the length of the longest of these segments. We define a diameter of the set to be any connecting segment of length dd. Prove that the number of diameters of the given set is at most nn.

1964

International Mathematical Olympiad 1964 Problem 3

A circle is inscribed in triangle ABCABC with sides a,b,ca, b, c. Tangents to the circle parallel to the sides of the triangle are constructed. Each of these tangents cuts off a triangle from ABC\triangle ABC. In each of these triangles, a circle is inscribed. Find the sum of the areas of all four inscribed circles (in terms of a,b,ca, b, c).

International Mathematical Olympiad 1964 Problem 6

In tetrahedron ABCDABCD, vertex DD is connected with D0D_0 the centroid of ABC\triangle ABC. Lines parallel to DD0DD_0 are drawn through A,BA, B and CC. These lines intersect the planes BCD,CADBCD, CAD and ABDABD in points A1,B1A_1, B_1 and C1C_1, respectively. Prove that the volume of ABCDABCD is one third the volume of A1B1C1D0A_1B_1C_1D_0. Is the result true if point D0D_0 is selected anywhere within ABC\triangle ABC?

1963

International Mathematical Olympiad 1963 Problem 4

Find all solutions x1,x2,x3,x4,x5x_1, x_2, x_3, x_4, x_5 of the system x5+x2=yx1x1+x3=yx2x2+x4=yx3x3+x5=yx4x4+x1=yx5,\begin{aligned} x_5 + x_2 &= yx_1\\ x_1 + x_3 &= yx_2\\ x_2 + x_4 &= yx_3\\ x_3 + x_5 &= yx_4\\ x_4 + x_1 &= yx_5, \end{aligned} where yy is a parameter.

International Mathematical Olympiad 1963 Problem 6

Five students, A,B,C,D,EA, B, C, D, E, took part in a contest. One prediction was that the contestants would finish in the order ABCDEABCDE. This prediction was very poor. In fact no contestant finished in the position predicted, and no two contestants predicted to finish consecutively actually did so. A second prediction had the contestants finishing in the order DAECBDAECB. This prediction was better. Exactly two of the contestants finished in the places predicted, and two disjoint pairs of students predicted to finish consecutively actually did so. Determine the order in which the contestants finished.

1962

International Mathematical Olympiad 1962 Problem 1

Find the smallest natural number nn which has the following properties:

(a) Its decimal representation has 6 as the last digit.

(b) If the last digit 6 is erased and placed in front of the remaining digits, the resulting number is four times as large as the original number nn.

International Mathematical Olympiad 1962 Problem 3

Consider the cube ABCDABCDABCDA'B'C'D' (ABCDABCD and ABCDA'B'C'D' are the upper and lower bases, respectively, and edges AA,BB,CC,DDAA',BB',CC',DD' are parallel). The point XX moves at constant speed along the perimeter of the square ABCDABCD in the direction ABCDAABCDA, and the point YY moves at the same rate along the perimeter of the square BCCBB'C'CB in the direction BCCBBB'C'CBB'. Points XX and YY begin their motion at the same instant from the starting positions AA and BB', respectively. Determine and draw the locus of the midpoints of the segments XYXY.

International Mathematical Olympiad 1962 Problem 7

The tetrahedron SABCSABC has the following property: there exist five spheres, each tangent to the edges SA,SB,SC,BC,CA,ABSA,SB,SC,BC,CA,AB, or to their extensions.

(a) Prove that the tetrahedron SABCSABC is regular.

(b) Prove conversely that for every regular tetrahedron five such spheres exist.

1961

International Mathematical Olympiad 1961 Problem 1

Solve the system of equations: x+y+z=ax2+y2+z2=b2xy=z2\begin{aligned} x + y + z &= a \\ x^2 + y^2 + z^2 &= b^2 \\ xy &= z^2 \end{aligned} where aa and bb are constants. Give the conditions that aa and bb must satisfy so that x,y,zx, y, z (the solutions of the system) are distinct positive numbers.

International Mathematical Olympiad 1961 Problem 4

Consider triangle P1P2P3P_1P_2P_3 and a point PP within the triangle. Lines P1P,P2P,P3PP_1P, P_2P, P_3P intersect the opposite sides in points Q1,Q2,Q3Q_1, Q_2, Q_3 respectively. Prove that, of the numbers P1PPQ1,P2PPQ2,P3PPQ3\frac{P_1P}{PQ_1}, \frac{P_2P}{PQ_2}, \frac{P_3P}{PQ_3} at least one is 2\leq 2 and at least one is 2\geq 2.

International Mathematical Olympiad 1961 Problem 6

Consider a plane ε\varepsilon and three non-collinear points A,B,CA, B, C on the same side of ε\varepsilon; suppose the plane determined by these three points is not parallel to ε\varepsilon. In plane ε\varepsilon take three arbitrary points A,B,CA', B', C'. Let L,M,NL, M, N be the midpoints of segments AA,BB,CCAA', BB', CC'; let GG be the centroid of triangle LMNLMN. (We will not consider positions of the points A,B,CA', B', C' such that the points L,M,NL, M, N do not form a triangle.) What is the locus of point GG as A,B,CA', B', C' range independently over the plane ε\varepsilon?

1960

International Mathematical Olympiad 1960 Problem 3

In a given right triangle ABCABC, the hypotenuse BCBC, of length aa, is divided into nn equal parts (nn an odd integer). Let α\alpha be the acute angle subtending, from AA, that segment which contains the midpoint of the hypotenuse. Let hh be the length of the altitude to the hypotenuse of the triangle. Prove: tanα=4nh(n21)a.\tan\alpha=\frac{4nh}{(n^{2}-1)a}.

International Mathematical Olympiad 1960 Problem 5

Consider the cube ABCDABCDABCDA^{\prime}B^{\prime}C^{\prime}D^{\prime} (with face ABCDABCD directly above face ABCDA^{\prime}B^{\prime}C^{\prime}D^{\prime}).

(a) Find the locus of the midpoints of segments XYXY, where XX is any point of ACAC and YY is any point of BDB^{\prime}D^{\prime}.

(b) Find the locus of points ZZ which lie on the segments XYXY of part (a) with ZY=2XZZY=2XZ.

International Mathematical Olympiad 1960 Problem 6

Consider a cone of revolution with an inscribed sphere tangent to the base of the cone. A cylinder is circumscribed about this sphere so that one of its bases lies in the base of the cone. Let V1V_{1} be the volume of the cone and V2V_{2} the volume of the cylinder.

(a) Prove that V1V2V_{1}\neq V_{2}.

(b) Find the smallest number kk for which V1=kV2V_{1}=kV_{2}, for this case, construct the angle subtended by a diameter of the base of the cone at the vertex of the cone.

International Mathematical Olympiad 1960 Problem 7

An isosceles trapezoid with bases aa and cc and altitude hh is given.

(a) On the axis of symmetry of this trapezoid, find all points PP such that both legs of the trapezoid subtend right angles at PP.

(b) Calculate the distance of PP from either base.

(c) Determine under what conditions such points PP actually exist. (Discuss various cases that might arise.)

1959

International Mathematical Olympiad 1959 Problem 2

For what real values of xx is

(x+2x1)+(x2x1)=A,\sqrt{(x+\sqrt{2x-1})}+\sqrt{(x-\sqrt{2x-1})}=A,

given (a) A=2A=\sqrt{2}, (b) A=1A=1, (c) A=2A=2, where only non-negative real numbers are admitted for square roots?

International Mathematical Olympiad 1959 Problem 3

Let a,b,ca,b,c be real numbers. Consider the quadratic equation in cosx\cos x:

acos2x+bcosx+c=0.a\cos^{2}x+b\cos x+c=0.

Using the numbers a,b,c,a,b,c, form a quadratic equation in cos2x\cos 2x, whose roots are the same as those of the original equation. Compare the equations in cosx\cos x and cos2x\cos 2x for a=4,b=2,c=1a=4,b=2,c=-1.

International Mathematical Olympiad 1959 Problem 5

An arbitrary point MM is selected in the interior of the segment ABAB. The squares AMCDAMCD and MBEFMBEF are constructed on the same side of ABAB, with the segments AMAM and MBMB as their respective bases. The circles circumscribed about these squares, with centers PP and QQ, intersect at MM and also at another point NN. Let NN' denote the point of intersection of the straight lines AFAF and BCBC.

(a) Prove that the points NN and NN' coincide.

(b) Prove that the straight lines MNMN pass through a fixed point SS independent of the choice of MM.

(c) Find the locus of the midpoints of the segments PQPQ as MM varies between AA and BB.

International Mathematical Olympiad 1959 Problem 6

Two planes, PP and QQ, intersect along the line pp. The point AA is given in the plane PP, and the point CC in the plane QQ; neither of these points lies on the straight line pp. Construct an isosceles trapezoid ABCDABCD (with ABAB parallel to CDCD) in which a circle can be inscribed, and with vertices BB and DD lying in the planes PP and QQ respectively.