A1. A circle has center on the side AB of the cyclic quadrilateral ABCD. The other three sides are tangent to the circle. Prove that AD + BC = AB.
A2. Let n and k be relatively prime positive integers with k < n. Each number in the set M = {1, 2, 3, ... , n-1} is colored either blue or white. For each i in M, both i and n-i have the same color. For each i in M not equal to k, both i and |i-k| have the same color. Prove that all numbers in M must have the same color.
A3. For any polynomial P(x) = a0 + a1x + ... + akxk with integer coefficients, the number of odd coefficients is denoted by o(P). For i = 0, 1, 2, ... let Qi(x) = (1 + x)i. Prove that if i1, i2, ... , in are integers satisfying 0 ≤ i1 < i2 < ... < in, then: o(Qi1 + Qi2 + ... + Qin) ≥ o(Qi1).
B1. Given a set M of 1985 distinct positive integers, none of which has a prime divisor greater than 23, prove that M contains a subset of 4 elements whose product is the 4th power of an integer.
B2. A circle center O passes through the vertices A and C of the triangle ABC and intersects the segments AB and BC again at distinct points K and N respectively. The circumcircles of ABC and KBN intersect at exactly two distinct points B and M. Prove that ∠OMB is a right angle.
B3. For every real number x1, construct the sequence x1, x2, ... by setting: xn+1 = xn(xn + 1/n).
Prove that there exists exactly one value of x1 which gives 0 < xn < xn+1 < 1 for all n.
Solutions
Problem A1
A circle has center on the side AB of the cyclic quadrilateral ABCD. The other three sides are tangent to the circle. Prove that AD + BC = AB.
Solution
Let the circle touch AD, CD, BC at L, M, N respectively. Take X on the line AD on the same side of A as D, so that AX = AO, where O is the center of the circle. Now the triangles OLX and OMC are congruent: OL = OM = radius of circle, ∠OLX = ∠OMC = 90o, and ∠OXL = 90o - A/2 = (180o - A)/2 = C/2 (since ABCD is cyclic) = ∠OCM. Hence LX = MC. So OA = AL + MC. Similarly, OB = BN + MD. But MC = CN and MD = DL (tangents have equal length), so AB = OA + OB = AL + LD + CN + NB = AD + BC.
Problem A2
Let n and k be relatively prime positive integers with k < n. Each number in the set M = {1, 2, 3, ... , n-1} is colored either blue or white. For each i in M, both i and n-i have the same color. For each i in M not equal to k, both i and |i-k| have the same color. Prove that all numbers in M must have the same color.
Solution
n and k are relatively prime, so 0, k, 2k, ... , (n-1)k form a complete set of residues mod n. So k, 2k, ... , (n-1)k are congruent to the numbers 1, 2, ... , n-1 in some order. Suppose ik is congruent to r and (i+1)k is congruent to s. Then either s = r + k, or s = r + k - n. If s = r + k, then we have immediately that r = s - k and s have the same color. If s = r + k - n, then r = n - (k - s), so r has the same color as k - s, and k - s has the same color as s. So in any case r and s have the same color. By giving i values from 1 to n-2 this establishes that all the numbers have the same color.
Problem A3
For any polynomial P(x) = a0 + a1x + ... + akxk with integer coefficients, the number of odd coefficients is denoted by o(P). For i = 0, 1, 2, ... let Qi(x) = (1 + x)i. Prove that if i1, i2, ... , in are integers satisfying 0 ≤ i1 < i2 < ... < in, then:
o(Qi1 + Qi2 + ... + Qin) ≥ o(Qi1).
Solution
If i is a power of 2, then all coefficients of Qi are even except the first and last. [There are various ways to prove this. Let iCr denote the rth coefficient, so iCr = i!/(r!(i-r)!). Suppose 0 < r < i. Then iCr = i-1Cr-1 i/r, but i-1Cr-1 is an integer and i is divisible by a higher power of 2 than r, hence iCr is even.]
Let Q = Qi1 + ... + Qin. We use induction on in. If in = 1, then we must have n = 2, i1 = 0, and i2 = 1, so Q = 2 + x, which has the same number of odd coefficients as Qi1 = 1. So suppose it is true for smaller values of in. Take m a power of 2 so that m ≤ in < 2m. We consider two cases i1 ≥ m and i1 < m.
Consider first i1 ≥ m. Then Qi1 = (1 + x)mA, Q = (1 + x)mB, where A and B have degree less than m. Moreover, A and B are of the same form as Qi1 and Q, (all the ijs are reduced by m, so we have o(A) ≤ o(B) by induction. Also o(Qi1) = o((1 + x)mA) = o(A + xmA) = 2o(A) ≤ 2o(B) = o(B + xmB) = o((1 + x)mB) = o(Q), which establishes the result for in.
It remains to consider the case i1 < m. Take r so that ir < m, ir+1 > m. Set A = Qi1 + ... + Qir, (1 + x)mB = Qir+1 + ... + Qin, so that A and B have degree < m. Then o(Q) = o(A + (1 + x)mB) = o(A + B + xmB) = o(A + B) + o(B). Now o(A - B) + o(B) >= o(A - B + B) = o(A), because a coefficient of A is only odd if just one of the corresponding coefficients of A - B and B is odd. But o(A - B) = o(A + B), because corresponding coefficients of A - B and A + B are either equal or of the same parity. Hence o(A + B) + o(B) ≥ o(A). But o(A) ≥ o(Qii) by induction. So we have established the result for in.
Problem B1
Given a set M of 1985 distinct positive integers, none of which has a prime divisor greater than 23, prove that M contains a subset of 4 elements whose product is the 4th power of an integer.
Solution
Suppose we have a set of at least 3.2n+1 numbers whose prime divisors are all taken from a set of n. So each number can be written as p1r1...pnrn for some non-negative integers ri, where pi is the set of prime factors common to all the numbers. We classify each ri as even or odd. That gives 2n possibilities. But there are more than 2n + 1 numbers, so two numbers have the same classification and hence their product is a square. Remove those two and look at the remaining numbers. There are still more than 2n + 1, so we can find another pair. We may repeat to find 2n + 1 pairs with a square product. [After removing 2n pairs, there are still 2n + 1 numbers left, which is just enough to find the final pair.] But we may now classify these pairs according to whether each exponent in the square root of their product is odd or even. We must find two pairs with the same classification. The product of these four numbers is now a fourth power.
Applying this to the case given, there are 9 primes less than or equal to 23 (2, 3, 5, 7, 11, 13, 17, 19, 23), so we need at least 3.512 + 1 = 1537 numbers for the argument to work (and we have 1985).
The key is to find the 4th power in two stages, by first finding lots of squares. If we try to go directly to a 4th power, this type of argument does not work (we certainly need more than 5 numbers to be sure of finding four which sum to 0 mod 4, and 59 is far too big).
Problem B2
A circle center O passes through the vertices A and C of the triangle ABC and intersects the segments AB and BC again at distinct points K and N respectively. The circumcircles of ABC and KBN intersect at exactly two distinct points B and M. Prove that angle OMB is a right angle.
Solution
The three radical axes of the three circles taken in pairs, BM, NK and AC are concurrent. Let X be the point of intersection. [They cannot all be parallel or B and M would coincide.] The first step is to show that XMNC is cyclic. The argument depends slightly on how the points are arranged. We may have: ∠XMN = 180o - ∠BMN = ∠BKN = 180o - ∠AKN = ∠ACN = 180o - ∠XCN, or we may have ∠XMN = 180o - ∠BMN = 180o - ∠BKN = ∠AKN = 180o - ∠ACN = 180o - ∠XCN.
Now XM.XB = XK.XN = XO2 - ON2. BM·BX = BN·BC = BO2 - ON2, so XM·XB - BM·BX = XO2 - BO2. But XM·XB - BM·BX = XB(XM - BM) = (XM + BM)(XM - BM) = XM2 - BM2. So XO2 - BO2 = XM2 - BM2. Hence OM is perpendicular to XB, or ∠OMB = 90o.
Problem B3
For every real number x1, construct the sequence x1, x2, ... by setting:
xn+1 = xn(xn + 1/n).
Prove that there exists exactly one value of x1 which gives 0 < xn < xn+1 < 1 for all n.
Solution
Define S0(x) = x, Sn(x) = Sn-1(x) (Sn-1(x) + 1/n). The motivation for this is that xn = Sn-1(x1).
Sn(0) = 0 and Sn(1) > 1 for all n > 1. Also Sn(x) has non-negative coefficients, so it is strictly increasing in the range [0,1]. Hence we can find (unique) solutions an, bn to Sn(an) = 1 - 1/n, Sn(bn) = 1.
Sn+1(an) = Sn(an) (Sn(an) + 1/n) = 1 - 1/n > 1 - 1/(n+1), so an < an+1. Similarly, Sn+1(bn) = Sn(bn) (Sn(bn) + 1/n) = 1 + 1/n > 1, so bn > bn+1. Thus an is an increasing sequence and bn is a decreasing sequence with all an less than all bn. So we can certainly find at least one point x1 which is greater than all the an and less than all the bn. Hence 1 - 1/n < Sn(x1) < 1 for all n. But Sn(x1) = xn+1. So xn+1 < 1 for all n. Also xn > 1 - 1/n implies that xn+1 = xn(xn + 1/n) > xn. Finally, we obviously have xn > 0. So the resulting series xn satisfies all the required conditions.
It remains to consider uniqueness. Suppose that there is an x1 satisfying the conditions given. Then we must have Sn(x1) lying in the range 1 - 1/n, 1 for all n. [The lower limit follows from xn+1 = xn(xn + 1/n).] Hence we must have an < x1 < bn for all n. We show uniqueness by showing that bn - an tends to zero as n tends to infinity. Since all the coefficients of Sn(x) are non-negative, it is has increasing derivative. Sn(0) = 0 and Sn(bn) = 1, so for any x in the range 0, bn we have Sn(x) ≤ x/bn. In particular, 1 - 1/n < an/bn. Hence bn - an ≤ bn - bn(1 - 1/n) = bn/n < 1/n, which tends to zero.
Read moreSolutions are also available in Murray S Klamkin, International Mathematical Olympiads 1978-1985, MAA 1986, and in István Reiman, International Mathematical Olympiad 1959-1999, ISBN 189-8855-48-X.
Labels:
IMO