Function theory on the annulus in the dp-norm

Abstract

In this paper we shall use realization theory to prove new results about a class of holomorphic functions on an annulus \[Rδ def= \z ∈ C: δ <|z|<1\,\] where 0<δ<1. The class of functions in question arises in the early work of R. G. Douglas and V. I. Paulsen on the rational dilation of a Hilbert space operator T to a normal operator with spectrum in ∂ Rδ. Their work suggested the following norm \|·\|dp on the space Hol(Rδ) of holomorphic functions on Rδ, \[ \|φ\|dp def= \ \|φ(T)\|: \|T\|≤ 1, \|T-1 \|≤ 1/δ \ and \ σ(T)⊂eq Rδ\.\] By analogy with the classical Schur class of holomorphic functions S with supremum norm at most 1 on the disc D, it is natural to consider the dp-Schur class Sdp of holomorphic functions of dp-norm at most 1 on Rδ. Our central result is a Pick interpolation theorem for functions in Sdp that is analogous to Abrahamse's Interpolation Theorem for bounded holomorphic functions on a multiply-connected domain. For a tuple λ=(λ1,…,λn) of distinct interpolation nodes in Rδ, we introduce a special set G dp(λ) of positive definite n× n matrices, which we call DP Szego kernels. The DP Pick problem λj zj, j=1,…,n, is shown to be solvable if and only if, \[ [(1- zi zj)gij] 0 \; for all\; g ∈ G dp (λ).\] We prove further that a solvable DP Pick problem has a solution which is a rational function.