Standard

Inverse problems for boundary triples with applications. / Brown, B. M.; Marletta, M.; Naboko, S.; Wood, I.

In: Studia Mathematica, Vol. 237, No. 3, 01.01.2017, p. 241-275.

Research output: Contribution to journalArticlepeer-review

Harvard

Brown, BM, Marletta, M, Naboko, S & Wood, I 2017, 'Inverse problems for boundary triples with applications', Studia Mathematica, vol. 237, no. 3, pp. 241-275. https://doi.org/10.4064/sm8613-11-2016

APA

Brown, B. M., Marletta, M., Naboko, S., & Wood, I. (2017). Inverse problems for boundary triples with applications. Studia Mathematica, 237(3), 241-275. https://doi.org/10.4064/sm8613-11-2016

Vancouver

Brown BM, Marletta M, Naboko S, Wood I. Inverse problems for boundary triples with applications. Studia Mathematica. 2017 Jan 1;237(3):241-275. https://doi.org/10.4064/sm8613-11-2016

Author

Brown, B. M. ; Marletta, M. ; Naboko, S. ; Wood, I. / Inverse problems for boundary triples with applications. In: Studia Mathematica. 2017 ; Vol. 237, No. 3. pp. 241-275.

BibTeX

@article{dbbef64c806547499e75facc7f6ad43f,
title = "Inverse problems for boundary triples with applications",
abstract = "This paper discusses the inverse problem of how much information on an operator can be determined/detected from 'measurements on the boundary'. Our focus is on non-selfadjoint operators and their detectable subspaces (these determine the part of the operator 'visible' from 'boundary measurements'). We show results in an abstract setting, where we consider the relation between the M- function (the abstract Dirichlet to Neumann map or the transfer matrix in system theory) and the resolvent bordered by projections onto the detectable subspaces. More specifically, we investigate questions of unique determination, reconstruction, analytic continuation and jumps across the essential spectrum. The abstract results are illustrated by examples of Schrodinger operators, matrixdifferential operators and, mostly, by multiplication operators perturbed by integral operators (the Friedrichs model), where we use a result of Widom to show that the detectable subspace can be characterized in terms of an eigenspace of a Hankel-like operator.",
keywords = "Detectable subspace, Friedrichs model, Inverse problem, M-function, Widom",
author = "Brown, {B. M.} and M. Marletta and S. Naboko and I. Wood",
year = "2017",
month = jan,
day = "1",
doi = "10.4064/sm8613-11-2016",
language = "English",
volume = "237",
pages = "241--275",
journal = "Studia Mathematica",
issn = "0039-3223",
publisher = "Instytut Matematyczny",
number = "3",

}

RIS

TY - JOUR

T1 - Inverse problems for boundary triples with applications

AU - Brown, B. M.

AU - Marletta, M.

AU - Naboko, S.

AU - Wood, I.

PY - 2017/1/1

Y1 - 2017/1/1

N2 - This paper discusses the inverse problem of how much information on an operator can be determined/detected from 'measurements on the boundary'. Our focus is on non-selfadjoint operators and their detectable subspaces (these determine the part of the operator 'visible' from 'boundary measurements'). We show results in an abstract setting, where we consider the relation between the M- function (the abstract Dirichlet to Neumann map or the transfer matrix in system theory) and the resolvent bordered by projections onto the detectable subspaces. More specifically, we investigate questions of unique determination, reconstruction, analytic continuation and jumps across the essential spectrum. The abstract results are illustrated by examples of Schrodinger operators, matrixdifferential operators and, mostly, by multiplication operators perturbed by integral operators (the Friedrichs model), where we use a result of Widom to show that the detectable subspace can be characterized in terms of an eigenspace of a Hankel-like operator.

AB - This paper discusses the inverse problem of how much information on an operator can be determined/detected from 'measurements on the boundary'. Our focus is on non-selfadjoint operators and their detectable subspaces (these determine the part of the operator 'visible' from 'boundary measurements'). We show results in an abstract setting, where we consider the relation between the M- function (the abstract Dirichlet to Neumann map or the transfer matrix in system theory) and the resolvent bordered by projections onto the detectable subspaces. More specifically, we investigate questions of unique determination, reconstruction, analytic continuation and jumps across the essential spectrum. The abstract results are illustrated by examples of Schrodinger operators, matrixdifferential operators and, mostly, by multiplication operators perturbed by integral operators (the Friedrichs model), where we use a result of Widom to show that the detectable subspace can be characterized in terms of an eigenspace of a Hankel-like operator.

KW - Detectable subspace

KW - Friedrichs model

KW - Inverse problem

KW - M-function

KW - Widom

UR - http://www.scopus.com/inward/record.url?scp=85018465520&partnerID=8YFLogxK

U2 - 10.4064/sm8613-11-2016

DO - 10.4064/sm8613-11-2016

M3 - Article

AN - SCOPUS:85018465520

VL - 237

SP - 241

EP - 275

JO - Studia Mathematica

JF - Studia Mathematica

SN - 0039-3223

IS - 3

ER -

ID: 36462557