Function theory in the bfd-norm on an elliptical region

Abstract

Let E be the open region in the complex plane bounded by an ellipse. The B. and F. Delyon norm \|·\|bfd on the space Hol(E) of holomorphic functions on E is defined by \|f\|bfd def= T∈ F bfd(E)\|f(T)\|, where F bfd(E) is the class of operators T such that the closure of the numerical range of T is contained in E. The name of the norm recognizes a celebrated theorem of the brothers Delyon, which implies that \|·\|bfd is equivalent to the supremum norm \|·\|∞ on Hol(E). The purpose of this paper is to develop the theory of holomorphic functions of bfd-norm less than or equal to one on E. To do so we shall employ a remarkable connection between the bfd norm on Hol(E) and the supremum norm \|·\|∞ on the space H∞(G) of bounded holomorphic functions on the symmetrized bidisc, the domain G in C2 defined by align* G & def= \(z+w,zw): |z|<1, |w|<1\. align* It transpires that there exists a holomorphic embedding τ:E G having the property that, for any bounded holomorphic function f on E, \[ \|f\|bfd = ∈f\\|F\|∞: F ∈ H∞(G), Fτ=f\, \] and moreover, the infimum is attained at some F ∈ H∞(G). This result allows us to derive, for holomorphic functions of bfd-norm at most one on E, analogs of the well-known model and realization formulae for Schur-class functions. We also give a second derivation of these models and realizations, which exploits the Zhukovskii mapping from an annulus onto E.

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