11th International Mathematical Olympiad 1969 Problems & Solutions



A1.  Prove that there are infinitely many positive integers m, such that n4 + m is not prime for any positive integer n.
A2.  Let f(x) = cos(a1 + x) + 1/2 cos(a2 + x) + 1/4 cos(a3 + x) + ... + 1/2n-1 cos(an + x), where ai are real constants and x is a real variable. If f(x1) = f(x2) = 0, prove that x1 - x2 is a multiple of π.
A3.  For each of k = 1, 2, 3, 4, 5 find necessary and sufficient conditions on a > 0 such that there exists a tetrahedron with k edges length a and the remainder length 1.
B1.  C is a point on the semicircle diameter AB, between A and B. D is the foot of the perpendicular from C to AB. The circle K1 is the in-circle of ABC, the circle K2 touches CD, DA and the semicircle, the circle K3 touches CD, DB and the semicircle. Prove that K1, K2 and K3 have another common tangent apart from AB.
B2.  Given n > 4 points in the plane, no three collinear. Prove that there are at least (n-3)(n-4)/2 convex quadrilaterals with vertices amongst the n points.
B3.  Given real numbers x1, x2, y1, y2, z1, z2, satisfying x1 > 0, x2 > 0, x1y1 > z12, and x2y2 > z22, prove that:       8/((x1 + x2)(y1 + y2) - (z1 + z2)2) ≤ 1/(x1y1 - z12) + 1/(x2y2 - z22).
Give necessary and sufficient conditions for equality. 

Solutions

Problem A1
Prove that there are infinitely many positive integers m, such that n4 + m is not prime for any positive integer n.
Solution
n4 + 4 r4 = (n2 + 2rn + 2r2)(n2 - 2rn + 2r2). Clearly the first factor is greater than 1, the second factor is (n - r)2 + r2, which is also greater than 1 for r greater than 1. So we may take m = 4 r4 for any r greater than 1. 

Problem A2
Let f(x) = cos(a1 + x) + 1/2 cos(a2 + x) + 1/4 cos(a3 + x) + ... + 1/2n-1 cos(an + x), where ai are real constants and x is a real variable. If f(x1) = f(x2) = 0, prove that x1 - x2 is a multiple of π.
Solution
f is not identically zero, because f(-a1) = 1 + 1/2 cos(a2 - a1) + ... > 1 - 1/2 - 1/4 - ... - 1/2n-1 > 0.
Using the expression for cos(x + y) we obtain f(x) = b cos x + c sin x, where b = cos a1 + 1/2 cos a2 + ... + 1/2n-1 cos an, and c = - sin a1 - 1/2 sin a2 - ... - 1/2n-1 sin an. b and c are not both zero, since f is not identically zero, so f(x) = √(b2 + c2) cos(d + x), where cos d = b/√(b2 + c2), and sin d = c/√(b2 + c2). Hence the roots of f(x) = 0 are just mπ + π/2 - d. 

Problem A3
For each of k = 1, 2, 3, 4, 5 find necessary and sufficient conditions on a > 0 such that there exists a tetrahedron with k edges length a and the remainder length 1.
Solution
A plodding question. Take the tetrahedron to be ABCD.
Take k = 1 and AB to have length a, the other edges length 1. Then we can hinge triangles ACD and BCD about CD to vary AB. The extreme values evidently occur with A, B, C, D coplanar. The least value, 0, when A coincides with B, and the greatest value √3, when A and B are on opposite sides of CD. We rule out the extreme values on the grounds that the tetrahedron is degenerate, thus obtaining 0 < a < √3.
For k = 5, the same argument shows that 0 < 1 < √3 a, and hence a > 1/√3.
For k = 2, there are two possible configurations: the sides length a adjacent, or not. Consider first the adjacent case. Take the sides length a to be AC and AD. As before, the two extreme cases gave A, B, C, D coplanar. If A and B are on opposite sides of CD, then a = √(2 - √3). If they are on the same side, then a = √(2 + √3). So this configuration allows any a satisfying √(2 - √3) < a < √(2 + √3).
The other configuration has AB = CD = a. One extreme case has a = 0. We can increase a until we reach the other extreme case with ADBC a square side 1, giving a = √2. So this configuration allows any a satisfying 0 < a < √2. Together, the two configurations allow any a satisfying: 0 < a < √(2 + √3).
This also solves the case k = 4, and allows any a satisfying: a > 1/√(2 + √3) = √(2 - √3).
For k = 3, any value of a > 0 is allowed. For a <= 1, we may take the edges length a to form a triangle. For a ≥ 1 we may take a triangle with unit edges and the edges joining the vertices to the fourth vertex to have length a.  


Problem B1
C is a point on the semicircle diameter AB, between A and B. D is the foot of the perpendicular from C to AB. The circle K1 is the in-circle of ABC, the circle K2 touches CD, DA and the semicircle, the circle K3 touches CD, DB and the semicircle. Prove that K1, K2 and K3 have another common tangent apart from AB.
Solution
Let the three centers be O1, O2 and O3. We show that O1 is the midpoint of O2O3. In fact it is sufficient to show that O1 lies on O2O3, because then we can reflect the known tangent AB in the line O2O3.
As usual, let AB = c, BC = a, CA = b. Let the in-circle touch AB at P, AC at Q and BC at R. Then since angle ACB = 90, O1QCR is a square. Also AQ = AP and BP = BR, so r1 = b - AP, and r1 = a - BP = a - (c - AP). Adding: r1 = (a + b - c)/2, and AP = (b + c - a)/2.
Let the circle center O2 touch AB at X, and the circle center O3 touch AB at Y. Let O be the midpoint of AB. Now consider the right-angled triangle OXO2. Since the circle center O2 touches the semicircle, OO2 = c/2 - r2. OX = OD + DX = (c/2 - AD) + r2. Also, by similar triangles, AD = b2/c. So, using Pythagoras: (c/2 - r2)2 = r22 + (c/2 - b2/c + r2)2. Multiplying out and rearranging: r22 - 2r2(c - b2/c) - (b2 - b4/c2). But ABC is right-angled, so c2 = a2 + b2, and hence c - b2/c = a2/c and b2 - b4/c2 = a2b2/c2. So r22 + 2r2 a2/c - a2b2/c2 = 0, which has roots r2 = a - a2/c (positive) and - a + a2/c (negative). So r2 = a - a2/c. Similarly, r3 = b - b2/c. So O2X + O3Y = XY = r2 + r3 = a + b - c = 2 r1.
XP = AP - AX = AP - (AD - DX) = (b + c - a)/2 - (b2/c - r2) = (b + c - a)/2 - (c - a) = (a + b - c)/2 = r1. We now have all we need: XP = PY = PO1, and XO2 + YO3 = 2 PO1.

 Problem B2
Given n > 4 points in the plane, no three collinear. Prove that there are at least (n-3)(n-4)/2 convex quadrilaterals with vertices amongst the n points.
Solution
(n-3)(n-4)/2 is a poor lower bound.
Observe first that any 5 points include 4 forming a convex quadrilateral. For take the convex hull. If it consists of more than 3 points, we are done. If not, it must consist of 3 points, A, B and C, with the other 2 points, D and E, inside the triangle ABC. Two vertices of the triangle must lie on the same side of the line DE and they form convex quadrilateral with D and E.
Given n points, we can choose 5 in n(n-1)(n-2)(n-3)(n-4)/120 different ways. Each choice gives us a convex quadrilateral, but any given convex quadrilateral may arise from n-4 different sets of 5 points, so we have at least n(n-1)(n-2)(n-3)/120 different convex quadrilaterals. We now show that n(n-1)(n-2)(n-3)/120 ≥ (n-3)(n-4)/2 for all n ≥ 5.
We wish to prove that n(n-1)(n-2) ≥ 60(n-4), or n(n-1)(n-2) - 60(n-4) ≥ 0. Trial shows equality for n = 5 and 6, so we can factorise and get (n-5)(n-6)(n+8), which is clearly at least 0 for n at least 5. 

Problem B3
Given real numbers x1, x2, y1, y2, z1, z2, satisfying x1 > 0, x2 > 0, x1y1 > z12, and x2y2 > z22, prove that:
      8/((x1 + x2)(y1 + y2) - (z1 + z2)2) ≤ 1/(x1y1 - z12) + 1/(x2y2 - z22).
Give necessary and sufficient conditions for equality.
Solution
Let a1 = x1y1 - z12 and a2 = x2y2 - z22. We apply the arithmetic/geometric mean result 3 times:
(1) to a12, a22, giving 2a1a2 ≤ a12 + a22;
(2) to a1, a2, giving √(a1a2) ≤ (a1 + a2)/2;
(3) to a1y2/y1, a2y1/y2, giving √(a1a2) ≤ (a1y2/y1 + a2y1/y2)/2;
We also use (z1/y1 - z2/y2)2 ≥ 0. Now x1y1 > z12 ≥ 0, and x1 > 0, so y1 > 0. Similarly, y2 > 0. So:
(4) y1y2(z1/y1 - z2/y2)2 ≥ 0, and hence z12y2/y1 + z22y1/y2 ≥ 2z1z2.
Using (3) and (4) gives 2√(a1a2) ≤ (x1y2 + x2y1) - (z12y2/y1 + z22y1/y2) ≤ (x1y2 + x2y1 - 2z1z2).
Multiplying by (2) gives: 4a1a2 ≤ (a1 + a2)(x1y2 + x2y1 - 2z1z2).
Adding (1) and 2a1a2 gives: 8a1a2 ≤ (a1 + a2)2 + (a1 + a2)(x1y2 + x2y1 - 2z1z2) = a(a1 + a2), where a = (x1 + x2)(y1 + y2) - (z1 + z2)2. Dividing by a1a2a gives the required inequality.
Equality requires a1 = a2 from (1), y1 = y2 from (2), z1 = z2 from (3), and hence x1 = x2. Conversely, it is easy to see that these conditions are sufficient for equality. 

Solutions are also available in:   Samuel L Greitzer, International Mathematical Olympiads 1959-1977, MAA 1978, and in   István Reiman, International Mathematical Olympiad 1959-1999, ISBN 189-8855-48-X.  


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