Representing maps for semibounded forms and their Lebesgue type decompositions
Abstract
For a semibounded sesquilinear form in a Hilbert space there exists a representing map from to another Hilbert space , such that , , with a lower bound of . Representing maps offer a simplifying tool to study general semibounded forms. By means of representing maps closedness, closability, and singularity of are immediately translated into the corresponding properties of the operator , and vice versa. Also properties of sum decompositions of a nonnegative form with two other nonnegative forms and in can be analyzed by means of associated nonnegative contractions . This helps, for instance, to establish an explicit operator theoretic characterization for the summands and to be, or not to be, mutually singular. Such sum decompositions are used to study characteristic properties of the so-called Lebesgue type decompositions of semibounded forms , where is closable and singular; in particular, this includes the Lebesgue decomposition of a semibounded form due to B. Simon. Furthermore, for a semibounded form with its representing map it will be shown that the corresponding semibounded selfadjoint relation is uniquely determined by a limit version of the classical representation theorem for the form , being studied by W. Arendt and T. ter Elst in a sectorial context. Via representing maps a full treatment is given of the convergence of monotone sequences of semibounded forms.
Cite
@article{arxiv.2401.00584,
title = {Representing maps for semibounded forms and their Lebesgue type decompositions},
author = {Seppo Hassi and Henk de Snoo},
journal= {arXiv preprint arXiv:2401.00584},
year = {2024}
}
Comments
29 pages