14th USA Mathematical Olympiad 1985 Problems

14th USA Mathematical Olympiad 1985 Problems

1.  Do there exist 1985 distinct positive integers such that the sum of their squares is a cube and the sum of their cubes is a square?

2.  Find all real roots of the quartic x⁴ - (2N + 1)x² - x + N² + N - 1 = 0 correct to 4 decimal places, where N = 10¹⁰.

3.  A tetrahedron has at most one edge longer than 1. What is the maximum total length of its edges?

4.  A graph has n > 2 points. Show that we can find two points A and B such that at least [n/2] - 1 of the remaining points are joined to either both or neither of A and B.

5.  0 < a₁ ≤ a₂ ≤ a₃ ≤ ... is an unbounded sequence of integers. Let b_n = m if a_m is the first member of the sequence to equal or exceed n. Given that a₁₉ = 85, what is the maximum possible value of a₁ + a₂ + ... + a₁₉ + b₁ + b₂ + ... + b₈₅?

Solution

14th USA Mathematical Olympiad 1985

Problem 1

Do there exist 1985 distinct positive integers such that the sum of their squares is a cube and the sum of their cubes is a square?

Solution

Answer: yes.

Take any n integers a_i. Suppose that ∑ a_i² = b and ∑ a_i³ = c. Now multiply each a_i by b⁴c³. The sum of their squares becomes b⁹c⁶ which is a cube and the sum of their cubes becomes b¹²c¹⁰ which is a square. Problem 2

Find all real roots of the quartic x⁴ - (2N + 1)x² - x + N² + N - 1 = 0 correct to 4 decimal places, where N = 10¹⁰.

Solution

Answer: 99999.9984 and 100000.0016.

We can write the equation as (x² - N - 1/2)² = x + 5/4. For x < -5/4 the lhs is positive and the rhs is negative, so there are no roots with x < -5/4. If x lies between -5/4 and 0, then the lhs is obviously much larger than the rhs, so again there is no root. Thus there are no negative roots. Descartes' rule of signs (see below) tells us that there are at most 2 positive roots.

If x = 10⁵, then the lhs is 1/4 and the rhs is much larger (approx 10⁵). If x = 10⁵ ± 1, then the lhs is (± 2 10⁵ + 1/2)² which is approximately 4 10¹⁰ and much larger than the rhs. So there is a root either side of 10⁵. Put x = 10⁵ ± k. Then we want (± 2k.10⁵ + k² - 1/2)² = 10⁵ + 5/4, or (4k²10⁵ - 1)10⁵ ± 2k(1-2k² )10⁵ - 5/4 = 0. So evidently we need approximately 4k² = 10^-5, or k = ± 0.0016. So it looks as though the roots are 10⁵ ± 0.0016 = 99999.9984 and 100000.0016.

Put x = 10⁵ ± 0.00155. Then (x² - 10¹⁰ - 1/2)² - x - 5/4 = (±310 - 1/2 + 0.00155²)² - 10⁵± 0.00155 - 5/4 < 311² - 10⁵ < 0. Put x = 10⁵ ± 0.00165, then (x² - 10¹⁰ - 1/2)² - x - 5/4 = (±330 -1/2 + 0.00165²)² - 10⁵ ± 0.00165 - 5/4 > 329² - 10⁵ - 2 > 0. So indeed one root lies between 10⁵ - 0.00165 and 10⁵ - 0.00155 and the other root lies between 10⁵ + 0.00155 and 10⁵ + 0.00165.

Descartes' rule of signs.

This states that if the number of sign changes in the coefficients of the polynomial is d, then the number of positive roots is d or d less an even number. So, for example, if the polynomial is x⁵ + 14.3 x⁴ - 34 x² - x + 3.2, then there are two sign changes (+14.3 to -34 and -1 to 3.2), so there are either 0 or 2 positive roots. Note that we ignore zero coefficients. If r is a positive root of p(-x) = 0, then -r is a negative root of p(x) = 0. So if we substitute -x for x in the polynomial and the number of sign changes is then d', then we can conclude that the number of negative roots of the polynomial is either d' or d' less an even number. With the example above we get -x⁵ + 14.3 x⁴ - 34 x² + x + 3.2, which has 3 sign changes. So the polynomial has 1 or 3 negative roots.

The proof is not difficult. The key idea is to show that if k is a positive root, so that p(x) = (x - k) q(x), then (1) p(x) has at least one more sign change than q(x), and (2) the difference between the number of sign changes is odd (note that the signs of the constant coefficients of p(x) and q(x) are different).

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Problem 3

A tetrahedron has at most one edge longer than 1. What is the maximum total length of its edges?

Solution

Answer: 5 + √3.

Suppose AB is the edge which may be longer than 1. Then if we rotate the triangle ACD about CD until A lies in the same plane as BCD and is on the opposite side of CD to B, then we maximise AB without changing any of the other side lengths. So the maximal configuration must be planar.

Now suppose we regard C and D as fixed and the other points as variable. Suppose CD = 2x (<= 1). Then A and B must both lie inside the circle center C radius 1 and inside the circle center D radius 1 and hence inside their intersection which is bounded by the two arcs XY (assuming they meet at X and Y). Obviously we maximise AC + AD + BC + BD by taking A at X and B at Y (or vice versa). We claim that that choice also maximises AB. Suppose that is true. Then it also maximises AC + AD + BC + BD + AB at 4 + 2(1 - x²)^1/2. So we now have to vary CD to maximise 2x + 4 + 2(1 - x²)^1/2. We show that x + (1 - x²)^1/2 is increasing for x <= 1/2 and hence that the maximum is at x = 1/2. Put x = sin t. Then we have x + (1 - x²)^1/2 = √2 sin(t + π/4) which is indeed increasing for x ≤ π/6.

It remains to prove the claim. Take the circle diameter XY. Then the two arcs both lie inside this circle. [Two circles intersect in at most two points, so each arc must lie entirely inside or entirely outside the circle center O and it obviously does not lie outside. ] But AB lies inside a chord of this circle The length of the chord cannot exceed the diameter of the circle (which is XY) and hence AB ≤ XY.

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Problem 4

A graph has n > 2 points. Show that we can find two points A and B such that at least [n/2] - 1 of the remaining points are joined to either both or neither of A and B.

Solution

Consider the number of pairs (X, {Y, Z}), where X, Y, Z are distinct points such that X is joined to just one of Y, Z. If X is joined to just k points, then there are just k(n - 1 - k) ≤ (n - 1)²/4 such pairs (X, {Y, Z}). Hence in total there are at most n(n - 1)²/4 such pairs. But there are n(n - 1)/2 possible {Y, Z}. So we must be able to find one of them {A, B} which belongs to at most [ (n - 1)/2 ] such pairs. Hence there are at least n - 2 - [ (n - 1)/2 ] = [n/2] - 1 points X which are joined to both of A and B or to neither of A and B. [If confused by the [ ], consider n = 2m and n = 2m+1 separately! ]

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Problem 5

0 < a₁ ≤ a₂ ≤ a₃ ≤ ... is an unbounded sequence of integers. Let b_n = m if a_m is the first member of the sequence to equal or exceed n. Given that a₁₉ = 85, what is the maximum possible value of a₁ + a₂ + ... + a₁₉ + b₁ + b₂ + ... + b₈₅?

Solution

We show that the only possible value of the sum is 85.20 = 1700.

That is certainly the value if all a_i = 85, for then all b_j = 1 and so the sum is 19·85 + 85·1 = 85·20. Now consider the general case. Suppose that we increase some a_i by 1 from k to k+1 (whilst preserving the property that a_i is increasing, so we must have a_i < a_i+1 before the increase). The effect of the increase is to change b_k+1 from i+1 to i, but not to change any other b_j. This is obvious if a_i-1 < a_i and a_i+1 > a_i + 1. If a_i-1 = a_i, then before the change b_k = i-1 (not i) and that is still true after the change. Equally, if a_i = a_i+1 after the change, then it is still true that b_k+1 changes from i+1 to i. Thus the overall effect of the increase is not to change the sum of the a_i plus the sum of the b_j. But by a series of such changes we convert any initial sequence to all a_i = 85.