Rapid detection and classification of airborne time-domain electromagnetic anomalies using weighted multi-linear regression

Maxime Claprood; Michel Chouteau; Li Zhen Cheng

doi:10.1071/EG08018

RESEARCH ARTICLE

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Rapid detection and classification of airborne time-domain electromagnetic anomalies using weighted multi-linear regression

Maxime Claprood ¹ ² ⁴ Michel Chouteau ¹ Li Zhen Cheng ³

+ Author Affiliations

- Author Affiliations

¹ École Polytechnique de Montréal, P.O. Box 6079, Centre-Ville Station, Montréal, Québec H3C 3A7, Canada.

² Present address: Monash University, School of Geosciences, Building 28, Clayton Campus, Wellington Road, Melbourne, Vic. 3800, Australia.

³ Université du Québec en Abitibi-Témiscamingue, 445 boul. de l’Université, Rouyn-Noranda, Québec J9X 5E4, Canada.

⁴ Corresponding author. Email: Max.Claprood@sci.monash.edu.au

Exploration Geophysics 39(3) 164-180 https://doi.org/10.1071/EG08018
Submitted: 26 April 2007 Published: 22 September 2008

Abstract

We propose a rapid and efficient methodology for the detection and interpretation of airborne time-domain electromagnetic anomalies generated by thin sheet-like volcanogenic massive sulphides (VMS) deposits in a resistive environment, which are representative of VMS deposits in the Canadian Shield.

In the first step of the approach, we use high-order statistics for the detection and the recognition of a MEGATEM anomaly as indicating a thin sheet-like VMS deposit with respect to three criteria of detection: the minimum level of detection, the length of detection, and the coherence of detection over time. We adapt these criteria in order to optimise the detection of thin sheet-like VMS deposits against geological noise models. Once the anomaly is detected and recognised as the response to a thin sheet conductor, we interpret the model geometry and physical property using attributes calculated from the MEGATEM anomaly. We develop a system of weighted multi-linear regression to find the most significant attributes to estimate the dip, depth, conductance, and dimensions of a thin sheet-like VMS deposit. Stepwise regression suggests that shape attributes are most significant to estimate dip while depth is most strongly estimated by size attributes. The most significant attribute to estimate the conductance is the time constant. The size is best estimated by attributes related to the size of the anomaly. We test the regression system on thin sheet models with excellent performance. Most of the parameters of the thin sheet models were estimated within an interval of confidence about the initial property. We further test the system by estimating properties of three VMS deposits in the Abitibi Greenstone Belt, Québec, Canada, for which the geometries and geological properties are known. Most parameters are estimated within the interval of confidence for ISO, a thin sheet body, while the estimates for New-Insco and Gallen show more variability caused by departure from the reference thin sheet model.

Key words: airborne, classification, detection, multi-linear regression, time-domain electromagnetic, thin sheet-like conductors.

Acknowledgments

The present study was initiated within the framework of the project: ‘Valorization of MEGATEM technology’ (http://web2.uqat.ca/urstm/megatem/). This project was made possible by the financial participation of Canada Economic Development – Québec Region and the Ministère du développement économique, de l’innovation et de l’exportation du Québec. We also thank all participants to MEGATEM Valorisation Project; Université du Québec en Abitibi (UQAT), École Polytechnique de Montréal, Noranda, division of Falconbridge (now Xstrata Zinc Ltd) and Fugro Airborne Surveys Ltd We are also indebted to Dr Art Raiche from CSIRO for giving us access to the Leroi Air thin sheet executable program. Finally, we would like to thank Professor Jim Macnae, Dr Peter Wolfgram and Dr Lindsay Thomas for constructive comments and suggestions that greatly helped to improve the initial submission.

References

Annan P. A. , 1974, The equivalent source method for electromagnetic scattering analysis and to geophysical application: Ph.D. thesis, Memorial University of Newfoundland.

Annan, P. A., and Lockwood, R., 1991, An application of airborne GEOTEM in Australian conditions: Exploration Geophysics 22, 5–12.
| Crossref | GoogleScholarGoogle Scholar | Claprood M. , 2005, Automatic classification of sheet-like MEGATEM anomalies: M.Sc. thesis, École Polytechnique de Montréal (in French).

Draper N. and Smith H. , 1981, Applied Regression Analysis: Wiley series in probability and mathematical statistics, John Wiley and Sons, USA.

Everett, M. E., Benavides, A., and Pierce, C. J., 2005, An experimental study of the time-domain electromagnetic response of a buried conductive plate: Geophysics 70, G1–G7.
| Crossref | GoogleScholarGoogle Scholar | Green D. , and Hunter A. , 2004, AEM target detection in geological noise, Expanded Abstract in ASEG 17^th Geophysical Conference and Exhibition, Australian Society of Exploration Geophysicists, Sydney 2004.

Kay S. , 1998, Fundamentals of statistical signal processing: Detection theory: Prentice-Hall PTR, USA.

Konstantaras, A., Varley, M., Vallianatos, F., Collins, G., and Holifield, P., 2004, A neuro-fuzzy approach to the reliable recognition of electric earthquake precursors: Natural Hazards and Earth System Sciences 4, 641–646.
Lowe C. , Thomas M. , and Morris W. , 1999, Geophysics in mineral exploration: Fundamentals and case histories, Geological Association of Canada, Short Course Notes Volume 14.

Malo-Lalande, C., Chouteau, M., Marcotte, D., and Boivin, M., 2005, Time-Domain electromagnetic data interpretation using moving-loop configurations for sheet-like base metal ore deposits in resistive hosts: Exploration Geophysics 36, 374–380.
| Crossref | GoogleScholarGoogle Scholar | Marcotte D. , 2000, Traitement statistique des données géologiques: École Polytechnique de Montréal (in French).

Marroquin I. , 1997, Processing and interpretation of VLF signals (in French): M.Sc. thesis, École Polytechnique de Montréal.

McNeill J. D. , Bosnar M. , and Levy G. M. , 1991, Time domain electromagnetic prospecting methods, in M. N. Nabighian, ed., Electromagnetic methods in applied geophysics, vol. 2: Soc. of Expl. Geophys., Appendix B, 484–489.

Nabighian M. N. , and Macnae J. C. , 1991, Time domain electromagnetic prospecting methods, in M. N. Nabighian, ed., Electromagnetic methods in applied geophysics, vol. 2: Soc. Expl. Geophys., 427–520.

Ogilvy, R., 1986, Theoretical transient EM response curves over a thin dipping dyke in free space – Separated inline loop configuration: Geophysical Prospecting 34, 769–788.
| Crossref | GoogleScholarGoogle Scholar | Raiche A. , 2004, P223E Basics Electromagnetic Modelling, CSIRO Exploration and Mining – Electromagnetic Modelling Group.

Smith, R. S., and Keating, P. B., 1996, The usefulness of multicomponent, time-domain airborne electromagnetic measurements: Geophysics 61, 74–81.
| Crossref | GoogleScholarGoogle Scholar |

Smith, R. S., and Salem, A. S., 2007, A discrete conductor transformation of airborne electromagnetic data: Near Surface Geophysics 5, 87–95.

Smith, R. S., Fountain, D., and Allard, M., 2003, The MEGATEM fixed-wing transient EM system applied to mineral exploration: a discovery case history: First Break 21, 73–77.

Vallée, M., Keating, P., Smith, R., and St-Hilaire, C., 2004, Estimating depth and model type using the continuous wavelet transform of magnetic data: Geophysics 69, 191–199.
| Crossref | GoogleScholarGoogle Scholar |

Wolfgram, P., and Golden, H., 2001, Airborne EM applied to sulphide nickel – Examples and analysis: Exploration Geophysics 32, 136–140.
| Crossref | GoogleScholarGoogle Scholar |