Polynomials orthogonal on the semicircle, II

Abstract

Generalizing previous work [2], we study complex polynomials {π k },π k (z)=z k +⋯, orthogonal with respect to a complex-valued inner product (f,g)=∫ 0 π f(e iθ)g(e iθ)w(e iθ)dθ. Under suitable assumptions on the “weight function”w, we show that these polynomials exist whenever Re ∫ 0 π w(e iθ)dθ≠0, and we express them in terms of the real polynomials orthogonal with respect to the weight functionw(x). We also obtain the basic three-term recurrence relation. A detailed study is made of the polynomials {π k } in the case of the Jacobi weight functionw(z)=(1−z)α(1+z)β, α>−1, and its special case $$\alpha = \beta = \lambda - \tfrac{1}{2}$$ (Gegenbauer weight). We show, in particular, that for Gegenbauer weights the zeros ofπ n are all simple and, ifn≥2, contained in the interior of the upper unit half disc. We strongly suspect that the same holds true for arbitrary Jacobi weights. Finally, for the Gegenbauer weight, we obtain a linear second-order differential equation forπ n (z). It has regular singular points atz=1, −1, ∞ (like Gegenbauer's equation) and an additional regular singular point on the negative imaginary axis, which depends onn.