Real-Root Preserving Differential Operator Representations of Orthogonal Polynomials

Abstract

In this paper, we study linear transformations of the form T[xn]=Pn(x) where \Pn(x)\ is an orthogonal polynomial system. Of particular interest is understanding when these operators preserve real-rootedness in polynomials. It is known that when the Pn(x) are the Hermite polynomials or standard Laguerre polynomials, the transformation T has this property. It is also known that the transformation T[xn]=Hnα(x), where Hnα(x) is the nth generalized Hermite Polynomial with real parameter α, has the differential operator representation T[xn]=e-α2D2xn. The main result of this paper is to prove that a differential operator of the form Σk=0∞ γkk! Dk induces a system of monic orthogonal polynomials if and only if Σk=0∞ γkk! Dk=γ0e- α2D2-β D where γ0,α,β ∈ C and α,γ0 ≠ 0. This operator will produce a shifted set of generalized Hermite polynomials when α ∈ R. We also express the transformation from the standard basis to the standard Laguerre basis, T[xn]=Ln(x) as a differential operator of the form Σk=0∞ pk(x)k! Dk where the pk are polynomials, an identity that has not previously been shown.