60th Putnam 1999


A1. Find polynomials a(x), b(x), c(x) such that \|a(x)\| - \|b(x)\| + c(x) = -1 for x < -1, 3x + 2 for -1 ≤ x ≤ 0, -2x + 2 for x > 0.
A2. Show that for some fixed positive n we can always express a polynomial with real coefficients which is nowhere negative as a sum of the squares of n polynomials.
A3. Let 1/(1 - 2x - x²) = s₀ + s₁x + s₂x² + ... . Prove that for some f(n) we have s_n² + s_n+1² = s_f(n).
A4. Let a_ij = i²j/(3ⁱ(j 3ⁱ + i 3^j)). Find ∑ a_ij where the sum is taken over all pairs of integers (i, j) with i, j > 0.
A5. Find a constant k such that for any polynomial f(x) of degree 1999, we have \|f(0)\| ≤ k ∫_-1¹ \|f(x)\| dx.
A6. u₁ = 1, u₂ = 2, u₃ = 24, u_n = (6 u_n-1²u_n-3 - 8 u_n-1u_n-2²)/(u_n-2u_n-3). Show that u_n is always a multiple of n.
B1. The triangle ABC has AC = 1, ∠ACB = 90^o, and ∠BAC = φ. D is the point between A and B such that AD = 1. E is the point between B and C such that ∠EDC = φ. The perpendicular to BC at E meets AB at F. Find lim_φ→0 EF.
B2. p(x) is a polynomial of degree n. q(x) is a polynomial of degree 2. p(x) = p''(x)q(x) and the roots of p(x) are not all equal. Show that the roots of p(x) are all distinct.
B3. Let R be the reals. Define f :[0, 1) x [0, 1) → R by f(x, y) = ∑ x^myⁿ, where the sum is taken over all pairs of positive integers (m, n) satisfying m ≥ n/2, n ≥ m/2. Find lim_{(x, y)→(1, 1)} (1 - xy²)(1 - x²y)f(x, y).
B4. Let R be the reals. f :R → R is three times differentiable, and f(x), f '(x), f ''(x), f '''(x) are all positive for all x. Also f(x) ≥ f '''(x) for all x. Show that f '(x) < 2 f(x) for all x.
B5. n is an integer greater than 2 and φ = 2π/n. A is the n x n matrix (a_ij), where a_ij = cos( (i + j)φ) for i ≠ j, 1 + cos(2 j φ) for i = j. Find det A.
B6. X is a finite set of integers greater than 1 such that for any positive integer n, we can find m ∈ X such that m divides n or is relatively prime to n. Show that X contains a prime or two elements whose greatest common divisor is prime.

To avoid possible copyright problems, I have changed the wording, but not the substance, of all the problems.