Series reversion in Calderón’s problem

Henrik Garde; Nuutti Hyvonen

doi:10.1090/MCOM/3729

Series reversion in Calderón’s problem

Henrik Garde^*, Nuutti Hyvonen

^*Corresponding author for this work

Aarhus University

Research output: Contribution to journal › Article › Scientific › peer-review

6 Citations (Scopus)

Abstract

This work derives explicit series reversions for the solution of Calderón’s problem. The governing elliptic partial differential equation is ∇ · (A∇u) = 0 in a bounded Lipschitz domain and with a matrix-valued coefficient. The corresponding forward map sends A to a projected version of a local Neumann-to-Dirichlet operator, allowing for the use of partial boundary data and finitely many measurements. It is first shown that the forward map is analytic, and subsequently reversions of its Taylor series up to specified orders lead to a family of numerical methods for solving the inverse problem with increasing accuracy. The convergence of these methods is shown under conditions that ensure the invertibility of the Fréchet derivative of the forward map. The introduced numerical methods are of the same computational complexity as solving the linearised inverse problem. The analogous results are also presented for the smoothened complete electrode model.

Original language	English
Pages (from-to)	1925-1953
Number of pages	29
Journal	Mathematics of Computation
Volume	91
DOIs	https://doi.org/10.1090/MCOM/3729
Publication status	Published - 2022
MoE publication type	A1 Journal article-refereed

Keywords

Calderon problem
Electrical impedance tomography
Series reversion

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10.1090/MCOM/3729

https://arxiv.org/abs/2105.03210

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@article{0682c6ff70484a7bbd967f73568b1168,

title = "Series reversion in Calder{\'o}n{\textquoteright}s problem",

abstract = "This work derives explicit series reversions for the solution of Calder{\'o}n{\textquoteright}s problem. The governing elliptic partial differential equation is ∇ · (A∇u) = 0 in a bounded Lipschitz domain and with a matrix-valued coefficient. The corresponding forward map sends A to a projected version of a local Neumann-to-Dirichlet operator, allowing for the use of partial boundary data and finitely many measurements. It is first shown that the forward map is analytic, and subsequently reversions of its Taylor series up to specified orders lead to a family of numerical methods for solving the inverse problem with increasing accuracy. The convergence of these methods is shown under conditions that ensure the invertibility of the Fr{\'e}chet derivative of the forward map. The introduced numerical methods are of the same computational complexity as solving the linearised inverse problem. The analogous results are also presented for the smoothened complete electrode model.",

keywords = "Calderon problem, Electrical impedance tomography, Series reversion",

author = "Henrik Garde and Nuutti Hyvonen",

note = "Funding Information: Received by the editor May 7, 2021, and, in revised form, September 6, 2021, and December 1, 2021. 2020 Mathematics Subject Classification. Primary 35R30, 41A58, 47H14. Key words and phrases. Calder{\'o}n problem, electrical impedance tomography, series reversion. This work was supported by the Academy of Finland (decision 336789) and the Aalto Science Institute (AScI). The first author was supported by The Research Foundation of DPhil Ragna Rask-Nielsen and is associated with the Aarhus University DIGIT Centre. The second author was supported by Jane and Aatos Erkko Foundation via the project Electrical impedance tomography—a novel method for improved diagnostics of stroke. Publisher Copyright: {\textcopyright} 2022. American Mathematical Society",

year = "2022",

doi = "10.1090/MCOM/3729",

language = "English",

volume = "91",

pages = "1925--1953",

journal = "Mathematics of Computation",

issn = "0025-5718",

publisher = "American Mathematical Society",

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TY - JOUR

T1 - Series reversion in Calderón’s problem

AU - Garde, Henrik

AU - Hyvonen, Nuutti

N1 - Funding Information: Received by the editor May 7, 2021, and, in revised form, September 6, 2021, and December 1, 2021. 2020 Mathematics Subject Classification. Primary 35R30, 41A58, 47H14. Key words and phrases. Calderón problem, electrical impedance tomography, series reversion. This work was supported by the Academy of Finland (decision 336789) and the Aalto Science Institute (AScI). The first author was supported by The Research Foundation of DPhil Ragna Rask-Nielsen and is associated with the Aarhus University DIGIT Centre. The second author was supported by Jane and Aatos Erkko Foundation via the project Electrical impedance tomography—a novel method for improved diagnostics of stroke. Publisher Copyright: © 2022. American Mathematical Society

PY - 2022

Y1 - 2022

N2 - This work derives explicit series reversions for the solution of Calderón’s problem. The governing elliptic partial differential equation is ∇ · (A∇u) = 0 in a bounded Lipschitz domain and with a matrix-valued coefficient. The corresponding forward map sends A to a projected version of a local Neumann-to-Dirichlet operator, allowing for the use of partial boundary data and finitely many measurements. It is first shown that the forward map is analytic, and subsequently reversions of its Taylor series up to specified orders lead to a family of numerical methods for solving the inverse problem with increasing accuracy. The convergence of these methods is shown under conditions that ensure the invertibility of the Fréchet derivative of the forward map. The introduced numerical methods are of the same computational complexity as solving the linearised inverse problem. The analogous results are also presented for the smoothened complete electrode model.

AB - This work derives explicit series reversions for the solution of Calderón’s problem. The governing elliptic partial differential equation is ∇ · (A∇u) = 0 in a bounded Lipschitz domain and with a matrix-valued coefficient. The corresponding forward map sends A to a projected version of a local Neumann-to-Dirichlet operator, allowing for the use of partial boundary data and finitely many measurements. It is first shown that the forward map is analytic, and subsequently reversions of its Taylor series up to specified orders lead to a family of numerical methods for solving the inverse problem with increasing accuracy. The convergence of these methods is shown under conditions that ensure the invertibility of the Fréchet derivative of the forward map. The introduced numerical methods are of the same computational complexity as solving the linearised inverse problem. The analogous results are also presented for the smoothened complete electrode model.

KW - Calderon problem

KW - Electrical impedance tomography

KW - Series reversion

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U2 - 10.1090/MCOM/3729

DO - 10.1090/MCOM/3729

M3 - Article

AN - SCOPUS:85129569454

SN - 0025-5718

VL - 91

SP - 1925

EP - 1953

JO - Mathematics of Computation

JF - Mathematics of Computation

ER -

Series reversion in Calderón’s problem

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-: Centre of Excellence of Inverse Modelling and Imaging

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Series reversion in Calderón’s problem

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Keywords

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-: Centre of Excellence of Inverse Modelling and Imaging

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