Data Fusion for Electromagnetic and Electrical Resistive Tomography Based on Maximum Likelihood
This paper presents a maximum likelihood based approach to data fusion for electromagnetic (EM) and electrical resistive (ER) tomography. The statistical maximum likelihood criterion is closely linked to the additive Fisher information measure, and it facilitates an appropriate weighting of the meas...
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Online Access: | http://dx.doi.org/10.1155/2011/617089 |
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doaj-59f76bf047b54628bda32d9978ed0cec2020-11-24T20:50:58ZengHindawi LimitedInternational Journal of Geophysics1687-885X1687-88682011-01-01201110.1155/2011/617089617089Data Fusion for Electromagnetic and Electrical Resistive Tomography Based on Maximum LikelihoodSven Nordebo0Mats Gustafsson1Therese Sjöden2Francesco Soldovieri3School of Computer Science, Physics, and Mathematics, Linnaeus University, 35195 Växjö, SwedenDepartment of Electrical and Information Technology, Lund University, P.O. Box 118, 22100 Lund, SwedenSchool of Computer Science, Physics, and Mathematics, Linnaeus University, 35195 Växjö, SwedenInstitute for Electromagnetic Sensing of the Environment, National Research Council, Street Diocleziano 328, 80124 Naples, ItalyThis paper presents a maximum likelihood based approach to data fusion for electromagnetic (EM) and electrical resistive (ER) tomography. The statistical maximum likelihood criterion is closely linked to the additive Fisher information measure, and it facilitates an appropriate weighting of the measurement data which can be useful with multiphysics inverse problems. The Fisher information is particularly useful for inverse problems which can be linearized similar to the Born approximation. In this paper, a proper scalar product is defined for the measurements and a truncated Singular Value Decomposition (SVD) based algorithm is devised which combines the measurement data of the two imaging modalities in a way that is optimal in the sense of maximum likelihood. As a multiphysics problem formulation with applications in geophysics, the problem of tunnel detection based on EM and ER tomography is studied in this paper. To illustrate the connection between the Green's functions, the gradients and the Fisher information, two simple and generic forward models are described in detail regarding two-dimensional EM and ER tomography, respectively.http://dx.doi.org/10.1155/2011/617089 |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Sven Nordebo Mats Gustafsson Therese Sjöden Francesco Soldovieri |
spellingShingle |
Sven Nordebo Mats Gustafsson Therese Sjöden Francesco Soldovieri Data Fusion for Electromagnetic and Electrical Resistive Tomography Based on Maximum Likelihood International Journal of Geophysics |
author_facet |
Sven Nordebo Mats Gustafsson Therese Sjöden Francesco Soldovieri |
author_sort |
Sven Nordebo |
title |
Data Fusion for Electromagnetic and Electrical Resistive Tomography Based on Maximum Likelihood |
title_short |
Data Fusion for Electromagnetic and Electrical Resistive Tomography Based on Maximum Likelihood |
title_full |
Data Fusion for Electromagnetic and Electrical Resistive Tomography Based on Maximum Likelihood |
title_fullStr |
Data Fusion for Electromagnetic and Electrical Resistive Tomography Based on Maximum Likelihood |
title_full_unstemmed |
Data Fusion for Electromagnetic and Electrical Resistive Tomography Based on Maximum Likelihood |
title_sort |
data fusion for electromagnetic and electrical resistive tomography based on maximum likelihood |
publisher |
Hindawi Limited |
series |
International Journal of Geophysics |
issn |
1687-885X 1687-8868 |
publishDate |
2011-01-01 |
description |
This paper presents a maximum likelihood based approach to data
fusion for electromagnetic (EM) and electrical resistive (ER) tomography.
The statistical maximum likelihood criterion is closely linked
to the additive Fisher information measure, and it facilitates an appropriate
weighting of the measurement data which can be useful with
multiphysics inverse problems. The Fisher information is particularly useful for inverse problems which
can be linearized similar to the Born approximation. In this paper, a
proper scalar product is defined for the measurements and a truncated
Singular Value Decomposition (SVD) based algorithm is devised which
combines the measurement data of the two imaging modalities in a way
that is optimal in the sense of maximum likelihood. As a multiphysics problem formulation with applications in geophysics,
the problem of tunnel detection based on EM and ER tomography
is studied in this paper. To illustrate the connection between the
Green's functions, the gradients and the Fisher information, two simple
and generic forward models are described in detail regarding two-dimensional
EM and ER tomography, respectively. |
url |
http://dx.doi.org/10.1155/2011/617089 |
work_keys_str_mv |
AT svennordebo datafusionforelectromagneticandelectricalresistivetomographybasedonmaximumlikelihood AT matsgustafsson datafusionforelectromagneticandelectricalresistivetomographybasedonmaximumlikelihood AT theresesjoden datafusionforelectromagneticandelectricalresistivetomographybasedonmaximumlikelihood AT francescosoldovieri datafusionforelectromagneticandelectricalresistivetomographybasedonmaximumlikelihood |
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1716803049381429248 |