English

Generalized boundary triples, Weyl functions and inverse problems

Functional Analysis 2017-06-27 v1

Abstract

With a closed symmetric operator AA in a Hilbert space H{\mathfrak H} a triple Π={H,Γ0,Γ1}\Pi=\{{\mathcal H},\Gamma_0,\Gamma_1\} of a Hilbert space H{\mathcal H} and two abstract trace operators Γ0\Gamma_0 and Γ1\Gamma_1 from AA^* to H{\mathcal H} is called a generalized boundary triple for AA^* if an abstract analogue of the second Green's formula holds. Various classes of generalized boundary triples are introduced and corresponding Weyl functions MM are investigated. The most important ones for applications are specific classes of (essentially) unitary boundary triples which guarantee that the Weyl functions of boundary triples are Nevanlinna functions on H{\mathcal H}, or at least they belong to the class of Nevanlinna families. The boundary condition Γ0f=0\Gamma_0f=0 determines a reference operator A0A_0. The case where A0A_0 is selfadjoint implies a relatively simple analysis, as the joint domain of the trace mappings Γ0\Gamma_0 and Γ1\Gamma_1 admits a von Neumann type decomposition. The case where A0A_0 is only essentially selfadjoint is more involved, but appears to be of great importance, for instance, in applications to PDEs and ODEs. Various classes of generalized boundary triples will be characterized in purely analytic terms via the Weyl function MM. These characterizations involve solving direct and inverse problems for specific classes of (unbounded) operator functions MM. One of the main results specifies the analytic properties of MM which guarantee that A0A_0 is essentially selfadjoint. In this study we also derive, for instance, Kre\u{\i}n-type resolvent formulas for the most general classes of unitary and isometric boundary triples appearing in the present work. All the main results are shown to have applications in the study of ordinary and partial differential operators.

Keywords

Cite

@article{arxiv.1706.07948,
  title  = {Generalized boundary triples, Weyl functions and inverse problems},
  author = {Vladimir Derkach and Seppo Hassi and Mark Malamud},
  journal= {arXiv preprint arXiv:1706.07948},
  year   = {2017}
}

Comments

104 pages

R2 v1 2026-06-22T20:28:30.597Z