Orthogonal polynomials on the unit circle: Verblunsky coefficients with some restrictions imposed on a pair of related real sequences

Abstract

It was shown recently that associated with a pair of real sequences \\cn\n=1∞, \dn\n=1∞\, with \dn\n=1∞ a positive chain sequence, there exists a unique nontrivial probability measure μ on the unit circle. The Verblunsky coefficients \αn\n=0∞ associated with the orthogonal polynomials with respect to μ are given by the relation αn-1=τn-1[1-2mn-icn1-icn], n ≥ 1, where τ0 = 1, τn=Πk=1n(1-ick)/(1+ick), n ≥ 1 and \mn\n=0∞ is the minimal parameter sequence of \dn\n=1∞. In this manuscript we consider this relation and its consequences by imposing some restrictions of sign and periodicity on the sequences \cn\n=1∞ and \mn\n=1∞. When the sequence \cn\n=1∞ is of alternating sign, we use information about the zeros of associated para-orthogonal polynomials to show that there is a gap in the support of the measure in the neighbourhood of z= -1. Furthermore, we show that it is possible to ge\-nerate periodic Verblunsky coefficients by choosing periodic sequences \cn\n=1∞ and \mn\n=1∞ with the additional restriction c2n=-c2n-1, \, n≥ 1. We also give some results on periodic Verblunsky coefficients from the point of view of positive chain sequences. An example is provided to illustrate the results obtained.