Transdimensional Monte Carlo Inversion of AEM Data

Ross C Brodie; Malcolm Sambridge

doi:10.1071/ASEG2012ab095

ISSN: 2202-0586
E-ISSN:

oa Transdimensional Monte Carlo Inversion of AEM Data
Authors Ross C Brodie^a and Malcolm Sambridge^b
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^a Geoscience Australia, GPO Box 378 Canberra, ACT 2601, [email protected] ^b Research School of Earth Sciences Australian National University, Canberra, , ACT 0200, [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2012, Issue ASEG2012 - 22nd Geophysical Conference, Dec 2012, p. 1 - 4
DOI: https://doi.org/10.1071/ASEG2012ab095
- Published online: 01 Dec 2012

Abstract

Summary

A new approach for the 1D inversion of AEM data has been developed. We use a reversible jump Markov Chain Monte Carlo method to perform Bayesian inference. The Earth is partitioned by a variable number of nonoverlapping cells defined by a 1D Voronoi tessellation. A cell is equivalent to a layer in conventional AEM inversion and has a corresponding conductivity value. The number and the position of the cells defining the geometry of the structure with depth, as well as their conductivities, are unknowns in the inversion.

The inversion is carried out with a fully non-linear parameter search method based on a transdimensional Markov chain. Many conductivity models, with variable numbers of layers, are generated via the Markov chain and information is extracted from the ensemble as a whole. The variability of the individual models in the ensemble represents the posterior distribution. Spatially averaging results is a form of ‘data-driven’ smoothing, without the need to impose a specific number of layers, an explicit smoothing function, or choose regularization parameters. The ensemble can also be examined to ascertain the most probable depths of the layer interfaces in the vertical structure.

The method is demonstrated with synthetic time-domain AEM data. The results show that an attractive feature of this method over conventional approaches is that rigorous information about the non-uniqueness and uncertainty of the solution is obtained. We also conclude that the method will also have utility for AEM system selection and investigation of calibration problems.

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References

Bodin, T., and Sambridge, M., 2009, Seismic tomography with the reversible jump algorithm. Geophysical Journal International 178, 1411-36.
Bodin, T., Sambridge, M., and Gallagher, K., 2009, A selfparametrizing partition model approach to tomographic inverse problems. Inverse Problems 25.
Brodie, R.C., 2010, Holistic inversion of airborne electromagnetic data. Ph.D. Thesis, Australian National University (http://hdl.handle.net/1885/49403).
Gallagher, K., Bodin, T., Sambridge, M., Weiss, D., Kylander, M., and Large, D., 2011, Inference of abrupt changes in noisy geochemical records using Bayesian Transdimensional changepoint models. Earth and Planetary Science Letters (in press).
Green, A., and Lane, R., 2003, Estimating noise levels in AEM data: 16th Geophysical Conference and Exhibition, Australian Society of Exploration Geophysicists, Extended Abstracts.
Lane, R., Green, A., Golding, C., Owers, M., Pik, P., Plunkett, C., Sattel, D., and Thorn, B., 2000, An example of 3D conductivity mapping using the TEMPEST airborne electromagnetic system. Exploration Geophysics 31, 162-72.
Mallick, K., and Verma, R.K., 1979, Time-domain electromagnetic sounding - computation of multi-layer response and the problem of equivalence in interpretation. Geophysical Prospecting 27, 137-54. Menke, W., 1989, Geophysical data analysis: discrete inverse theory. Academic Press.
Message-Passing-Interface-Forum, 1994, MPI: A messagepassing interface standard. International Journal of Supercomputing Applications 8, 165-416.
Minsley, B.J., 2011, A trans-dimensional Bayesian Markov chain Monte Carlo algorithm for model assessment using frequency-domain electromagnetic data. Geophysical Journal International Early View Online (doi: 10.1111/j.1365- 246X.2011.05165.x).
Yin, C., and Hodges, G., 2007, Simulated annealing for airborne EM inversion. Geophysics 72, F189-F195.

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Article Type: Research Article

Keyword(s): AEM; Bayesian; inversion; Monte Carlo.; transdimensional

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