SIPPI: A Matlab toolbox for sampling the solution to inverse problems with complex prior information Part 1-Methodology

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Standard

SIPPI : A Matlab toolbox for sampling the solution to inverse problems with complex prior information Part 1-Methodology. / Hansen, Thomas Mejer; Cordua, Knud Skou; Looms, Majken Caroline; Mosegaard, Klaus.

In: Computers & Geosciences, Vol. 52, 01.03.2013, p. 470-480.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Hansen, TM, Cordua, KS, Looms, MC & Mosegaard, K 2013, 'SIPPI: A Matlab toolbox for sampling the solution to inverse problems with complex prior information Part 1-Methodology', Computers & Geosciences, vol. 52, pp. 470-480. https://doi.org/10.1016/j.cageo.2012.09.004

APA

Hansen, T. M., Cordua, K. S., Looms, M. C., & Mosegaard, K. (2013). SIPPI: A Matlab toolbox for sampling the solution to inverse problems with complex prior information Part 1-Methodology. Computers & Geosciences, 52, 470-480. https://doi.org/10.1016/j.cageo.2012.09.004

Vancouver

Hansen TM, Cordua KS, Looms MC, Mosegaard K. SIPPI: A Matlab toolbox for sampling the solution to inverse problems with complex prior information Part 1-Methodology. Computers & Geosciences. 2013 Mar 1;52:470-480. https://doi.org/10.1016/j.cageo.2012.09.004

Author

Hansen, Thomas Mejer ; Cordua, Knud Skou ; Looms, Majken Caroline ; Mosegaard, Klaus. / SIPPI : A Matlab toolbox for sampling the solution to inverse problems with complex prior information Part 1-Methodology. In: Computers & Geosciences. 2013 ; Vol. 52. pp. 470-480.

Bibtex

@article{9634f21c3eaa4deca0e1f40e5e453711,
title = "SIPPI: A Matlab toolbox for sampling the solution to inverse problems with complex prior information Part 1-Methodology",
abstract = "From a probabilistic point-of-view, the solution to an inverse problem can be seen as a combination of independent states of information quantified by probability density functions. Typically, these states of information are provided by a set of observed data and some a priori information on the solution. The combined states of information (i.e. the solution to the inverse problem) is a probability density function typically referred to as the a posteriori probability density function. We present a generic toolbox for Matlab and Gnu Octave called SIPPI that implements a number of methods for solving such probabilistically formulated inverse problems by sampling the a posteriori probability density function. In order to describe the a priori probability density function, we consider both simple Gaussian models and more complex (and realistic) a priori models based on higher order statistics. These a priori models can be used with both linear and non-linear inverse problems. For linear inverse Gaussian problems we make use of least-squares and kriging-based methods to describe the a posteriori probability density function directly. For general nonlinear (i.e. non-Gaussian) inverse problems, we make use of the extended Metropolis algorithm to sample the a posteriori probability density function. Together with the extended Metropolis algorithm, we use sequential Gibbs sampling that allow computationally efficient sampling of complex a priori models. The toolbox can be applied to any inverse problem as long as a way of solving the forward problem is provided. Here we demonstrate the methods and algorithms available in SIPPI. An application of SIPPI, to a tomographic cross borehole inverse problems, is presented in a second part of this paper. (C) 2012 Elsevier Ltd. All rights reserved.",
keywords = "Inversion, Nonlinear, Sampling, A priori, A posteriori, SIMULATION",
author = "Hansen, {Thomas Mejer} and Cordua, {Knud Skou} and Looms, {Majken Caroline} and Klaus Mosegaard",
year = "2013",
month = mar,
day = "1",
doi = "10.1016/j.cageo.2012.09.004",
language = "English",
volume = "52",
pages = "470--480",
journal = "Computers & Geosciences",
issn = "0098-3004",
publisher = "Pergamon Press",

}

RIS

TY - JOUR

T1 - SIPPI

T2 - A Matlab toolbox for sampling the solution to inverse problems with complex prior information Part 1-Methodology

AU - Hansen, Thomas Mejer

AU - Cordua, Knud Skou

AU - Looms, Majken Caroline

AU - Mosegaard, Klaus

PY - 2013/3/1

Y1 - 2013/3/1

N2 - From a probabilistic point-of-view, the solution to an inverse problem can be seen as a combination of independent states of information quantified by probability density functions. Typically, these states of information are provided by a set of observed data and some a priori information on the solution. The combined states of information (i.e. the solution to the inverse problem) is a probability density function typically referred to as the a posteriori probability density function. We present a generic toolbox for Matlab and Gnu Octave called SIPPI that implements a number of methods for solving such probabilistically formulated inverse problems by sampling the a posteriori probability density function. In order to describe the a priori probability density function, we consider both simple Gaussian models and more complex (and realistic) a priori models based on higher order statistics. These a priori models can be used with both linear and non-linear inverse problems. For linear inverse Gaussian problems we make use of least-squares and kriging-based methods to describe the a posteriori probability density function directly. For general nonlinear (i.e. non-Gaussian) inverse problems, we make use of the extended Metropolis algorithm to sample the a posteriori probability density function. Together with the extended Metropolis algorithm, we use sequential Gibbs sampling that allow computationally efficient sampling of complex a priori models. The toolbox can be applied to any inverse problem as long as a way of solving the forward problem is provided. Here we demonstrate the methods and algorithms available in SIPPI. An application of SIPPI, to a tomographic cross borehole inverse problems, is presented in a second part of this paper. (C) 2012 Elsevier Ltd. All rights reserved.

AB - From a probabilistic point-of-view, the solution to an inverse problem can be seen as a combination of independent states of information quantified by probability density functions. Typically, these states of information are provided by a set of observed data and some a priori information on the solution. The combined states of information (i.e. the solution to the inverse problem) is a probability density function typically referred to as the a posteriori probability density function. We present a generic toolbox for Matlab and Gnu Octave called SIPPI that implements a number of methods for solving such probabilistically formulated inverse problems by sampling the a posteriori probability density function. In order to describe the a priori probability density function, we consider both simple Gaussian models and more complex (and realistic) a priori models based on higher order statistics. These a priori models can be used with both linear and non-linear inverse problems. For linear inverse Gaussian problems we make use of least-squares and kriging-based methods to describe the a posteriori probability density function directly. For general nonlinear (i.e. non-Gaussian) inverse problems, we make use of the extended Metropolis algorithm to sample the a posteriori probability density function. Together with the extended Metropolis algorithm, we use sequential Gibbs sampling that allow computationally efficient sampling of complex a priori models. The toolbox can be applied to any inverse problem as long as a way of solving the forward problem is provided. Here we demonstrate the methods and algorithms available in SIPPI. An application of SIPPI, to a tomographic cross borehole inverse problems, is presented in a second part of this paper. (C) 2012 Elsevier Ltd. All rights reserved.

KW - Inversion

KW - Nonlinear

KW - Sampling

KW - A priori

KW - A posteriori

KW - SIMULATION

U2 - 10.1016/j.cageo.2012.09.004

DO - 10.1016/j.cageo.2012.09.004

M3 - Journal article

VL - 52

SP - 470

EP - 480

JO - Computers & Geosciences

JF - Computers & Geosciences

SN - 0098-3004

ER -

ID: 335428395