Root geometry of polynomial sequences II: Type (1,0)

Abstract

We consider the sequence of polynomials Wn(x) defined by the recursion Wn(x)=(ax+b)Wn-1(x)+dWn-2(x), with initial values W0(x)=1 and W1(x)=t(x-r), where a,b,d,t,r are real numbers, a,t>0, and d<0. We show that every polynomial Wn(x) is distinct-real-rooted, and that the roots of the polynomial Wn(x) interlace the roots of the polynomial Wn-1(x). We find that, as n∞, the sequence of smallest roots of the polynomials Wn(x) converges decreasingly to a real number, and that the sequence of largest roots converges increasingly to a real number. Moreover, by using the Dirichlet approximation theorem, we prove that there is a number to which, for every positive integer i2, the sequence of ith smallest roots of the polynomials Wn(x) converges. Similarly, there is a number to which, for every positive integer i2, the sequence of ith largest roots of the polynomials Wn(x) converges. It turns out that these two convergence points are independent of the numbers t and r, as well as i. We derive explicit expressions for these four limit points, and we determine completely when some of these limit points coincide.