Optimality of Curtiss Bound on Poincare Multiplier for Positive Univariate Polynomials

Abstract

Let f be a monic univariate polynomial with non-zero constant term. We say that f is positive if f(x) is positive over all x≥0. If all the coefficients of f are non-negative, then f is trivially positive. In 1883, Poincar\'e proved thatf is positive if and only if there exists a monic polynomial g such that all the coefficients of gf are non-negative. Such polynomial g is called a Poincar\'e multiplier for the positive polynomial f. Of course one hopes to find a multiplier with smallest degree. This naturally raised a challenge: find an upper bound on the smallest degree of multipliers. In 1918, Curtiss provided such a bound. Curtiss also showed that the bound is optimal (smallest) when degree of f is 1 or 2. It is easy to show that the bound is not optimal when degree of f is higher. The Curtiss bound is a simple expression that depends only on the angle (argument) of non-real roots of f. In this paper, we show that the Curtiss bound is optimal among all the bounds that depends only on the angles.