An iterative approach to optimising depth to magnetic source using the spectral method

Anthony (Tony) Meixner; Stephen Johnston

doi:10.1071/ASEG2012ab214

ISSN: 2202-0586
E-ISSN:

oa An iterative approach to optimising depth to magnetic source using the spectral method
Authors Anthony (Tony) Meixner^a and Stephen Johnston^b
View Affiliations Hide Affiliations

^a Geoscience Australia, GPO Box 378 ACT, Australia, , 2601, [email protected] ^b Geoscience Australia, GPO Box 378 ACT, Australia, , 2601, [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/ASEG2012ab214
- Published online: 01 Dec 2012

Abstract

Summary

Knowledge of the depth of cover is poor across large areas of Australia. The spectral method is an efficient method of producing reliable depth to magnetic basement estimates across large regions of the continent.

A semi-automated work-flow has been created that enables the generation of depth to magnetic source estimates from windowed magnetic data using the Spector and Grant method. The work-flow allows for the correction of the power spectra, prior to the picking of straight-line segments, to account for the fractal distribution of magnetic sources. The fractal parameter (β) varies with depth and was determined by picking multiple depth estimates in regions of outcropping magnetic basement which have been upward continued to different levels in order to simulate different amounts of burial beneath non-magnetic sediments. A power law function best approximates the decay of β with depth.

An iterative schema used to determine the optimum β where the depths of magnetic sources are unknown, has been incorporated into the workflow. Preliminary testing in a region of known magnetic basement depth has produced encouraging results, although further testing is required. The decrease of β with increasing depth suggests that the fractal distribution of magnetisation becomes less correlated, or fractal, over larger volumes of observation.

Article metrics loading...

/content/journals/10.1071/ASEG2012ab214

2012-12-01

2026-01-18

From This Site

/content/journals/10.1071/ASEG2012ab214

dcterms_title,dcterms_subject,pub_keyword

-contentType:Journal -contentType:Contributor -contentType:Concept -contentType:Institution

10

5

Full text loading...

References

Bhattacharyya, B.K., 1966, Continuous spectrum of the totalmagnetic- field anomaly due to a rectangular prismatic body: Geophysics Vol. 31 (1), 97-121.
Fedi, M., Quarta, T., and De Santis, A., 1997, Inherent powerlaw behaviour of magnetic field power spectra from a Spector and Grant ensemble: Geophysics Vol. 62 (4), 1143-1150.
Kositcin, N., Champion, D.C., and Huston, D.L., 2009, Geodynamic synthesis of the north Queensland region and implications for metallogeny: Geoscience Australia Record 2009/30, 196 pp.
Myers, J.S., 1995, The generation and assembly of an Archaean supercontinent: evidence from the Yilgarn Craton, Western Australia: Geological Society. Special Publications 95, 143-154.
Pilkington, M., and Todoeshuck, J.P., 1993, Fractal magnetization of continental crust: Geophysical Research Letters, Vol. 20, No. 7, 627-630.
Pilkington, M., and Todoeshuck, J.P., 1995, Scaling nature of crustal susceptibilities: Geophysical Research Letters, Vol. 22, No. 7, 779-782.
Raymond, O.L., and Retter, A.J., (editors), 2010, Surface geology of Australia 1:1,000,000 scale, 2010 edition [digital dataset]: Geoscience Australia, Commonwealth of Australia, Canberra. http://ww.ga.gov.au.
Spector, A., and Grant, F.S., 1970, Statistical models for interpreting aeromagnetic data: Geophysics Vol. 35 (2), 293- 302.
Wade, B.P., Kelsey, D.E., Hand, M., and Barovich, K.M., 2008, The Musgrave Province: Stitching north, west and south Australia: Precambrian Research, Vol 166 (1-4), 370-38.

/content/journals/10.1071/ASEG2012ab214

Article Type: Research Article

Keyword(s): depth to magnetic basement; fractal; magnetisation.; spectral method

Most Cited This Month Most Cited RSS feed

- Inversion of data from electrical imaging surveys in water-covered areas
  
  Authors M. H. Loke and J. W. Lane
- Inversion of Magnetic Data from Remanent and Induced Sources
  
  Authors Robert G. Elllis, Barrry de Wet and Ian N. Macleod
- A comparison of smooth and blocky inversion methods in 2-D electrical imaging surveys
  
  Authors M. H. Loke, Ian Acworth and Torleif Dahlin
- Designing matched bandpass and azimuthal filters for the separation of potential-field anomalies by source region and source type
  
  Authors Jeffrey D. Phillips
- Bad Colour Maps Hide Big Features and Create False Anomalies
  
  Authors Peter Kovesi
- Practical 3D EM inversion – the P223F software suite
  
  Authors Art Raiche, Fred Sugeng and Glenn Wilson
- Estimating Noise Levels in AEM Data
  
  Authors Andy Green and Richard Lane
- Target delineation using Full Tensor Gravity Gradiometry data
  
  Authors Colm A. Murphy and James Brewster
- Transdimensional Monte Carlo Inversion of AEM Data
  
  Authors Ross C Brodie and Malcolm Sambridge
- The geotech VTEM time domain helicopter em system
  
  Authors Ken Witherly, Richard Irvine and Edward Morrison
More Less

oa An iterative approach to optimising depth to magnetic source using the spectral method

Abstract

Most Read This Month

Most Cited This Month Most Cited RSS feed