Orthogonal Polynomials, Verblunsky Coefficients, and a Szego-Verblunsky Theorem on the Unit Sphere in Cd

Abstract

Given a measure μ on the unit sphere ∂Bd in Cd with Lebesgue decomposition d μ = w \, d σ + d μs, with respect to the rotation-invariant Lebesgue measure σ on ∂ Bd, we introduce notions of orthogonal polynomials (α)α ∈ N0d, Verblunsky coefficients (γα,β)α,β ∈ N0d, and an associated Christoffel function λ∞(d)(z; d μ), and we prove a recurrence relation for the orthogonal polynomials involving the Verblunsky coefficients reminiscent of the classical Szego recurrences, as well as an analogue of Verblunsky's theorem. Moreover, we establish a number of equalities involving the orthogonal polynomials, determinants of moment matrices, and the Christoffel function, and show that if supp\, μs is discrete, then the aforementioned quantities depend only on the absolutely continuous part of μ. If, in addition to supp\, μs being discrete, one is able to find f ∈ H∞(Bd) such that f(0) = 1 and ∫∂ Bd |f(ζ)|2 w(ζ) dσ(ζ) ≤ ( ∫∂ Bd (w(ζ)) \, dσ(ζ) ), then we establish a d-variate Szego-Verblunsky theorem, namely Πα ∈ N0d (1 - | γ0,α |2) = (∫∂Bd ( w(ζ)) \, dσ(ζ)). Finally, we identify several classes of weights where one may construct such an f and highlight an explicit example of a weight w, residing outside of these classes, where Πα ∈ N0d (1 - |γ0,α |2) ≠ (∫∂Bd ( w(ζ)) \, dσ(ζ)).

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