Prove: The sum of the distances of the vertices of a regular tetrahedron from the center of its circumscribed sphere is less than the sum of the distances of these vertices from any other point in space.
International Mathematical Olympiad
Overview
| Year | P1 | P2 | P3 | P4 | P5 | P6 | P7 | Solved |
|---|---|---|---|---|---|---|---|---|
| 2025 | 0/6 | |||||||
| 2024 | 0/6 | |||||||
| 2023 | 0/6 | |||||||
| 2022 | 0/6 | |||||||
| 2021 | 0/6 | |||||||
| 2020 | 0/6 | |||||||
| 2019 | 0/6 | |||||||
| 2018 | 0/6 | |||||||
| 2017 | 0/6 | |||||||
| 2016 | 0/6 | |||||||
| 2015 | 0/6 | |||||||
| 2014 | 0/6 | |||||||
| 2013 | 0/6 | |||||||
| 2012 | 0/6 | |||||||
| 2011 | 0/6 | |||||||
| 2010 | 0/6 | |||||||
| 2009 | 0/6 | |||||||
| 2008 | 0/6 | |||||||
| 2007 | 0/6 | |||||||
| 2006 | 0/6 | |||||||
| 2005 | 0/6 | |||||||
| 2004 | 0/6 | |||||||
| 2003 | 0/6 | |||||||
| 2002 | 0/6 | |||||||
| 2001 | 0/6 | |||||||
| 2000 | 0/6 | |||||||
| 1999 | 0/6 | |||||||
| 1998 | 0/6 | |||||||
| 1997 | 0/6 | |||||||
| 1996 | 0/6 | |||||||
| 1995 | 0/6 | |||||||
| 1994 | 0/6 | |||||||
| 1993 | 0/6 | |||||||
| 1992 | 0/6 | |||||||
| 1991 | 0/6 | |||||||
| 1990 | 0/6 | |||||||
| 1989 | 0/6 | |||||||
| 1988 | 0/6 | |||||||
| 1987 | 0/6 | |||||||
| 1986 | 0/6 | |||||||
| 1985 | 0/6 | |||||||
| 1984 | 0/6 | |||||||
| 1983 | 0/6 | |||||||
| 1982 | 0/6 | |||||||
| 1981 | 0/6 | |||||||
| 1979 | 0/6 | |||||||
| 1978 | 0/6 | |||||||
| 1977 | 0/6 | |||||||
| 1976 | 0/6 | |||||||
| 1975 | 0/6 | |||||||
| 1974 | 0/6 | |||||||
| 1973 | 0/6 | |||||||
| 1972 | 0/6 | |||||||
| 1971 | 0/6 | |||||||
| 1970 | 0/6 | |||||||
| 1969 | 0/6 | |||||||
| 1968 | 0/6 | |||||||
| 1967 | 0/6 | |||||||
| 1966 | 0/6 | |||||||
| 1965 | 0/6 | |||||||
| 1964 | 0/6 | |||||||
| 1963 | 0/6 | |||||||
| 1962 | 0/7 | |||||||
| 1961 | 0/6 | |||||||
| 1960 | 0/7 | |||||||
| 1959 | 0/6 |
Documents
Problems
1966
Prove that for every natural number , and for every real number ( any integer)
Solve the system of equations where are four different real numbers.
In the interior of sides of triangle , any points , respectively, are selected. Prove that the area of at least one of the triangles is less than or equal to one quarter of the area of triangle .
1965
Determine all values in the interval which satisfy the inequality
Consider the system of equations
with unknowns . The coefficients satisfy the conditions:
(a) 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 .
Given the tetrahedron whose edges and have lengths and respectively. The distance between the skew lines and is , and the angle between them is . Tetrahedron is divided into two solids by plane , parallel to lines and . The ratio of the distances of from and is equal to . Compute the ratio of the volumes of the two solids obtained.
Find all sets of four real numbers such that the sum of any one and the product of the other three is equal to 2.
Consider with acute angle . Through a point perpendiculars are drawn to and , the feet of which are and respectively. The point of intersection of the altitudes of is . What is the locus of if is permitted to range over (a) the side , (b) the interior of ?
In a plane a set of points () is given. Each pair of points is connected by a segment. Let be the length of the longest of these segments. We define a diameter of the set to be any connecting segment of length . Prove that the number of diameters of the given set is at most .
1964
(a) Find all positive integers for which is divisible by 7.
(b) Prove that there is no positive integer for which is divisible by 7.
Suppose are the sides of a triangle. Prove that
A circle is inscribed in triangle with sides . Tangents to the circle parallel to the sides of the triangle are constructed. Each of these tangents cuts off a triangle from . In each of these triangles, a circle is inscribed. Find the sum of the areas of all four inscribed circles (in terms of ).
Seventeen people correspond by mail with one another - each one with all the rest. In their letters only three different topics are discussed. Each pair of correspondents deals with only one of these topics. Prove that there are at least three people who write to each other about the same topic.
Suppose five points in a plane are situated so that no two of the straight lines joining them are parallel, perpendicular, or coincident. From each point perpendiculars are drawn to all the lines joining the other four points. Determine the maximum number of intersections that these perpendiculars can have.
In tetrahedron , vertex is connected with the centroid of . Lines parallel to are drawn through and . These lines intersect the planes and in points and , respectively. Prove that the volume of is one third the volume of . Is the result true if point is selected anywhere within ?
1963
Find all real roots of the equation where is a real parameter.
Point and segment are given. Determine the locus of points in space which are vertices of right angles with one side passing through , and the other side intersecting the segment .
In an -gon all of whose interior angles are equal, the lengths of consecutive sides satisfy the relation Prove that .
Find all solutions of the system where is a parameter.
Prove that .
Five students, , took part in a contest. One prediction was that the contestants would finish in the order . 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 . 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
Find the smallest natural number 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 .
Determine all real numbers which satisfy the inequality:
Consider the cube ( and are the upper and lower bases, respectively, and edges are parallel). The point moves at constant speed along the perimeter of the square in the direction , and the point moves at the same rate along the perimeter of the square in the direction . Points and begin their motion at the same instant from the starting positions and , respectively. Determine and draw the locus of the midpoints of the segments .
Solve the equation .
On the circle there are given three distinct points Construct (using only straightedge and compasses) a fourth point on such that a circle can be inscribed in the quadrilateral thus obtained.
Consider an isosceles triangle. Let be the radius of its circumscribed circle and the radius of its inscribed circle. Prove that the distance between the centers of these two circles is
The tetrahedron has the following property: there exist five spheres, each tangent to the edges , or to their extensions.
(a) Prove that the tetrahedron is regular.
(b) Prove conversely that for every regular tetrahedron five such spheres exist.
1961
Solve the system of equations: where and are constants. Give the conditions that and must satisfy so that (the solutions of the system) are distinct positive numbers.
Let be the sides of a triangle, and its area. Prove: . In what case does equality hold?
Solve the equation , where is a natural number.
Consider triangle and a point within the triangle. Lines intersect the opposite sides in points respectively. Prove that, of the numbers at least one is and at least one is .
Construct triangle if , and , where is the midpoint of segment and . Prove that a solution exists if and only if In what case does the equality hold?
Consider a plane and three non-collinear points on the same side of ; suppose the plane determined by these three points is not parallel to . In plane take three arbitrary points . Let be the midpoints of segments ; let be the centroid of triangle . (We will not consider positions of the points such that the points do not form a triangle.) What is the locus of point as range independently over the plane ?
1960
Determine all three-digit numbers having the property that is divisible by 11, and is equal to the sum of the squares of the digits of .
For what values of the variable does the following inequality hold:
In a given right triangle , the hypotenuse , of length , is divided into equal parts ( an odd integer). Let be the acute angle subtending, from , that segment which contains the midpoint of the hypotenuse. Let be the length of the altitude to the hypotenuse of the triangle. Prove:
Construct triangle , given (the altitudes from and ) and , the median from vertex .
Consider the cube (with face directly above face ).
(a) Find the locus of the midpoints of segments , where is any point of and is any point of .
(b) Find the locus of points which lie on the segments of part (a) with .
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 be the volume of the cone and the volume of the cylinder.
(a) Prove that .
(b) Find the smallest number for which , for this case, construct the angle subtended by a diameter of the base of the cone at the vertex of the cone.
An isosceles trapezoid with bases and and altitude is given.
(a) On the axis of symmetry of this trapezoid, find all points such that both legs of the trapezoid subtend right angles at .
(b) Calculate the distance of from either base.
(c) Determine under what conditions such points actually exist. (Discuss various cases that might arise.)
1959
Prove that the fraction is irreducible for every natural number .
For what real values of is
given (a) , (b) , (c) , where only non-negative real numbers are admitted for square roots?
Let be real numbers. Consider the quadratic equation in :
Using the numbers form a quadratic equation in , whose roots are the same as those of the original equation. Compare the equations in and for .
Construct a right triangle with given hypotenuse such that the median drawn to the hypotenuse is the geometric mean of the two legs of the triangle.
An arbitrary point is selected in the interior of the segment . The squares and are constructed on the same side of , with the segments and as their respective bases. The circles circumscribed about these squares, with centers and , intersect at and also at another point . Let denote the point of intersection of the straight lines and .
(a) Prove that the points and coincide.
(b) Prove that the straight lines pass through a fixed point independent of the choice of .
(c) Find the locus of the midpoints of the segments as varies between and .
Two planes, and , intersect along the line . The point is given in the plane , and the point in the plane ; neither of these points lies on the straight line . Construct an isosceles trapezoid (with parallel to ) in which a circle can be inscribed, and with vertices and lying in the planes and respectively.