On the Fourier coefficients of powers of a Blaschke factor and strongly annular fonctions

Abstract

We compute asymptotic formulas for the k th Fourier coefficients of bλn, where bλ(z)=z-λ1-λ z is the Blaschke factor associated to λ∈D, k∈[0,∞) and n is a large integer. We distinguish several regions of different asymptotic behavior of those coefficients in terms of k and n. Given β∈((1-λ)/(1+λ),(1+λ)/(1-λ)) their decay is oscillatory for k∈[β n,n/β]. Given α∈(0,(1-λ)/(1+λ)) their decay is exponential for k∈[0,nα][n/α,∞). Airy-type behavior is happening near the k-transition points n(1-λ)/(1+λ) and n(1+λ)/(1-λ). The asymptotic formulas for the k th Fourier coefficients of bλn are derived using standard tools of asymptotic analysis of Laplace-type integrals. More precisely, the integral defining the k th Fourier coefficient of bλn is perfectly suited for an application of the method of stationary phase when k∈(n(1-λ)/(1+λ),n(1+λ)/(1-λ)) and requires the use of the method of the steepest descent when k[n(1-λ)/(1+λ),n(1+λ)/(1-λ)]. Uniform versions of those standard methods are required when k approaches one of the boundaries n(1-λ)/(1+λ), n(1+λ)/(1-λ). As an application, we construct strongly annular functions with Taylor coefficients satisfying sharp summation properties.