12th International Mathematical Olympiad 1970 Problems & Solutions



A1.  M is any point on the side AB of the triangle ABC. r, r1, r2 are the radii of the circles inscribed in ABC, AMC, BMC. q is the radius of the circle on the opposite side of AB to C, touching the three sides of AB and the extensions of CA and CB. Similarly, q1 and q2. Prove that r1r2q = rq1q2.
A2.  We have 0 ≤ xi < b for i = 0, 1, ... , n and xn > 0, xn-1 > 0. If a > b, and xnxn-1...x0 represents the number A base a and B base b, whilst xn-1xn-2...x0 represents the number A' base a and B' base b, prove that A'B < AB'.
A3.  The real numbers a0, a1, a2, ... satisfy 1 = a0 ≤ a1 ≤ a2 ≤ ... . b1, b2, b3, ... are defined by bn = ∑1≤k≤n (1 - ak-1/ak)/√ak. (a)  Prove that 0 ≤ bn < 2.
(b)  Given c satisfying 0 ≤ c < 2, prove that we can find an so that bn > c for all sufficiently large n.
B1.  Find all positive integers n such that the set {n, n+1, n+2, n+3, n+4, n+5} can be partitioned into two subsets so that the product of the numbers in each subset is equal.
B2.  In the tetrahedron ABCD, angle BDC = 90o and the foot of the perpendicular from D to ABC is the intersection of the altitudes of ABC. Prove that:       (AB + BC + CA)2 ≤ 6(AD2 + BD2 + CD2).
When do we have equality?
B3.  Given 100 coplanar points, no 3 collinear, prove that at most 70% of the triangles formed by the points have all angles acute. 

Solutions

Problem A1
M is any point on the side AB of the triangle ABC. r, r1, r2 are the radii of the circles inscribed in ABC, AMC, BMC. q is the radius of the circle on the opposite side of AB to C, touching the three sides of AB and the extensions of CA and CB. Similarly, q1 and q2. Prove that r1r2q = rq1q2.
 
Solution
We need an expression for r/q. There are two expressions, one in terms of angles and the other in terms of sides. The latter is a poor choice, because it is both harder to derive and less useful. So we derive the angle expression.
Let I be the center of the in-circle for ABC and X the center of the external circle for ABC. I is the intersection of the two angle bisectors from A and B, so c = r (cot A/2 + cot B/2). The X lies on the bisector of the external angle, so angle XAB is 90o - A/2. Similarly, angle XBA is 90o - B/2, so c = q (tan A/2 + tan B/2). Hence r/q = (tan A/2 + tan B/2)/(cot A/2 + cot B/2) = tan A/2 tan B/2.
Applying this to the other two triangles, we get r1/q1 = tan A/2 tan CMA/2, r2/q2 = tan B/2 tan CMB/2. But CMB/2 = 90o - CMA/2, so tan CMB/2 = 1/tan CMA/2. Hence result. 

Problem A2
We have 0 ≤ xi < b for i = 0, 1, ... , n and xn > 0, xn-1 > 0. If a > b, and xnxn-1...x0 represents the number A base a and B base b, whilst xn-1xn-2...x0 represents the number A' base a and B' base b, prove that A'B < AB'.
 
Solution
We have anbm > bnam for n > m. Hence anB' > bnA'. Adding anbn to both sides gives anB > bnA. Hence xnanB > xnbnA. But xnan = A - A' and xnbn = B - B', so (A - A')B > (B - B')A. Hence result.
Note that the only purpose of requiring xn-1 > 0 is to prevent A' and B' being zero. 

Problem A3
The real numbers a0, a1, a2, ... satisfy 1 = a0 <= a1 ≤ a2 <= ... . b1, b2, b3, ... are defined by bn = sum for k = 1 to n of (1 - ak-1/ak)/√ak.
(a)  Prove that 0 ≤ bn < 2.
(b)  Given c satisfying 0 ≤ c < 2, prove that we can find an so that bn > c for all sufficiently large n.
 
Solution
(a)  Each term of the sum is non-negative, so bn is non-negative. Let ck = √ak. Then the kth term = (1 - ak-1/ak)/√ak = ck-12/ck (1/ak-1 - 1/ak) = ck-12/ck (1/ck-1 + 1/ck)(1/ck-1 - 1/ck). But ck-12/ck (1/ck-1 + 1/ck) ≤ 2, so the kth term ≤ 2(1/ck-1 - 1/ck). Hence bn <= 2 - 2/cn < 2.
(b)  Let ck = dk, where d is a constant > 1, which we will choose later. Then the kth term is (1 - 1/d2)1/dk, so bn = (1 - 1/d2)(1 - 1/dn+1)/(1 - 1/d) = (1 + 1/d)(1 - 1/dn+1). Now take d sufficiently close to 1 that 1 + 1/d > c, and then take n sufficiently large so that (1 + 1/d)(1 - 1/dn+1) > c.

Problem B1
Find all positive integers n such that the set {n, n+1, n+2, n+3, n+4, n+5} can be partitioned into two subsets so that the product of the numbers in each subset is equal.
 
Solution
The only primes dividing numbers in the set can be 2, 3 or 5, because if any larger prime was a factor, then it would only divide one number in the set and hence only one product. Three of the numbers must be odd. At most one of the odd numbers can be a multiple of 3 and at most one can be a multiple of 5. The other odd number cannot have any prime factors. The only such number is 1, so the set must be {1, 2, 3, 4, 5, 6}, but that does not work because only one of the numbers is a multiple of 5. So there are no such sets. 

Problem B2
In the tetrahedron ABCD, angle BDC = 90o and the foot of the perpendicular from D to ABC is the intersection of the altitudes of ABC. Prove that:
      (AB + BC + CA)2 ≤ 6(AD2 + BD2 + CD2).
When do we have equality?
 
Solution
The first step is to show that angles ADB and ADC are also 90o. Let H be the intersection of the altitudes of ABC and let CH meet AB at X. Planes CED and ABC are perpendicular and AB is perpendicular to the line of intersection CE. Hence AB is perpendicular to the plane CDE and hence to ED. So BD2 = DE2 + BE2. Also CB2 = CE2 + BE2. Subtracting: CB2 - BD2 = CE2 - DE2. But CB2 - BD2 = CD2, so CE2 = CD2 + DE2, so angle CDE = 90o. But angle CDB = 90o, so CD is perpendicular to the plane DAB, and hence angle CDA = 90o. Similarly, angle ADB = 90o.
Hence AB2 + BC2 + CA2 = 2(DA2 + DB2 + DC2). But now we are done, because Cauchy's inequality gives (AB + BC + CA)2 ≤ 3(AB2 + BC2 + CA2).
We have equality iff we have equality in Cauchy's inequality, which means AB = BC = CA. 

Problem B3
Given 100 coplanar points, no 3 collinear, prove that at most 70% of the triangles formed by the points have all angles acute.
 
Solution
Improved and corrected by Gerhard Wöginger, Technical University Graz
At most 3 of the triangles formed by 4 points can be acute. It follows that at most 7 out of the 10 triangles formed by any 5 points can be acute. For given 10 points, the maximum no. of acute triangles is: the no. of subsets of 4 points x 3/the no. of subsets of 4 points containing 3 given points. The total no. of triangles is the same expression with the first 3 replaced by 4. Hence at most 3/4 of the 10, or 7.5, can be acute, and hence at most 7 can be acute.
The same argument now extends the result to 100 points. The maximum number of acute triangles formed by 100 points is: the no. of subsets of 5 points x 7/the no. of subsets of 5 points containing 3 given points. The total no. of triangles is the same expression with 7 replaced by 10. Hence at most 7/10 of the triangles are acute.

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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