On the Operators with Numerical Range in an Ellipse
Abstract
We give new necessary and sufficient conditions for the numerical range W(T) of an operator T ∈ B(H) to be a subset of the closed elliptical set Kδ ⊂eq C given by \[ Kδ def= \x+iy: x2(1+δ)2 + y2(1-δ)2 ≤ 1\, \] where 0 < δ < 1. Here B(H) denotes the collection of bounded linear operators on a Hilbert space H. Central to our efforts is a direct generalization of Berger's well-known criterion for an operator to have numerical radius at most one, his so-called strange dilation theorem. We next generalize the lemma of Sarason that describes power dilations in terms of semi-invariant subspaces to operators T that satisfy appropriate dilation properties. This generalization yields a characterization of the operators T∈ B(H) such that W(T) is contained in Kδ in terms of certain structured contractions that act on H H. As a corollary of our results we extend Ando's parametrization of operators having numerical range in a disc to those T such that W(T)⊂eq Kδ. We prove that, if T acts on a finite-dimensional Hilbert space H, then W(T)⊂eq Kδ if and only if there exist a pair of contractions A,B ∈ B(H) such that A is self-adjoint and \[ T=2δ A + (1-δ)1+A\ B1-A. \] We also obtain a formula for the B. and F. Delyon calcular norm of an analytic function on the inside of an ellipse in terms of the extremal H∞-extension problem for analytic functions defined on a slice of the symmetrized bidisc.
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