The Dulmage-Mendelsohn permutation in seismic tomography
The Dulmage-Mendelsohn permutation in seismic tomography
Seismic tomography inverse problems are among the largest high-dimensional parameter estimation tasks in Earth science. Although iterative algorithms can be used to efficiently solve these problems, their size gives rise to several issues such as the intractability of the computation of the model resolution and the model posterior covariance matrices that provide the means of assessing the robustness of the solution. In this work, we utilize methods from combinatorics and graph theory to study the structure of typical regional seismic body-wave tomography problems, and to effectively decompose them into subsets that can be solved efficiently by means of the least squares method. In combination with recent high performance direct sparse algorithms, this reduction in dimensionality allows for an efficient computation of the model resolution and covariance matrices using limited resources. We apply this methodology to a moderate size imaging of the structure of the crust and the upper mantle beneath Japan using deep local earthquakes recorded by the High Sensitivity Seismograph Network stations. Among the prominent features that are being imaged is a strong low-velocity region beneath the subducting Pacific slab along the entire Japan trench.
inverse theory, seismic tomography, Japan, computational seismology
Bogiatzis, Petros
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Ishii, Miaki
23e2086f-de0d-43e8-99c1-20f29eb718b0
Davis, Timothy A
205ba5b3-bde2-44e6-9469-b5799e0a6f2e
Bogiatzis, Petros
8fc5767f-51a2-4d3f-aab9-1ee9cfa9272d
Ishii, Miaki
23e2086f-de0d-43e8-99c1-20f29eb718b0
Davis, Timothy A
205ba5b3-bde2-44e6-9469-b5799e0a6f2e
Bogiatzis, Petros, Ishii, Miaki and Davis, Timothy A
(2019)
The Dulmage-Mendelsohn permutation in seismic tomography.
Geophysical Journal International.
(doi:10.1093/gji/ggz216).
Abstract
Seismic tomography inverse problems are among the largest high-dimensional parameter estimation tasks in Earth science. Although iterative algorithms can be used to efficiently solve these problems, their size gives rise to several issues such as the intractability of the computation of the model resolution and the model posterior covariance matrices that provide the means of assessing the robustness of the solution. In this work, we utilize methods from combinatorics and graph theory to study the structure of typical regional seismic body-wave tomography problems, and to effectively decompose them into subsets that can be solved efficiently by means of the least squares method. In combination with recent high performance direct sparse algorithms, this reduction in dimensionality allows for an efficient computation of the model resolution and covariance matrices using limited resources. We apply this methodology to a moderate size imaging of the structure of the crust and the upper mantle beneath Japan using deep local earthquakes recorded by the High Sensitivity Seismograph Network stations. Among the prominent features that are being imaged is a strong low-velocity region beneath the subducting Pacific slab along the entire Japan trench.
Text
ggz216
- Accepted Manuscript
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e-pub ahead of print date: 14 May 2019
Keywords:
inverse theory, seismic tomography, Japan, computational seismology
Identifiers
Local EPrints ID: 430981
URI: http://eprints.soton.ac.uk/id/eprint/430981
ISSN: 0956-540X
PURE UUID: 19bd318b-d453-4c57-9c87-7bc312f6d8d2
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Date deposited: 21 May 2019 16:30
Last modified: 16 Mar 2024 01:53
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Contributors
Author:
Petros Bogiatzis
Author:
Miaki Ishii
Author:
Timothy A Davis
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