Numerical shadows: measures and densities on the numerical range
Abstract
For any operator acting on an -dimensional Hilbert space we introduce its numerical shadow, which is a probability measure on the complex plane supported by the numerical range of . The shadow of at point is defined as the probability that the inner product is equal to , where stands for a random complex vector from , satisfying . In the case of N=2 the numerical shadow of a non-normal operator can be interpreted as a shadow of a hollow sphere projected on a plane. A similar interpretation is provided also for higher dimensions. For a hermitian its numerical shadow forms a probability distribution on the real axis which is shown to be a one dimensional -spline. In the case of a normal the numerical shadow corresponds to a shadow of a transparent solid simplex in onto the complex plane. Numerical shadow is found explicitly for Jordan matrices , direct sums of matrices and in all cases where the shadow is rotation invariant. Results concerning the moments of shadow measures play an important role. A general technique to study numerical shadow via the Cartesian decomposition is described, and a link of the numerical shadow of an operator to its higher-rank numerical range is emphasized.
Cite
@article{arxiv.1010.4189,
title = {Numerical shadows: measures and densities on the numerical range},
author = {Charles F. Dunkl and Piotr Gawron and John A. Holbrook and Zbigniew Puchała and Karol Życzkowski},
journal= {arXiv preprint arXiv:1010.4189},
year = {2011}
}
Comments
37 pages, 8 figures