Compensation of the full magnetic tensor gradient signal

Dominik Argast; Des FitzGerald; Horst Holstein; Ronny Stolz; Andreas Chwala

doi:10.1081/22020586.2010.12042011

ISSN: 2202-0586
E-ISSN:

oa Compensation of the full magnetic tensor gradient signal
Authors Dominik Argast^a, Des FitzGerald^b, Horst Holstein^c, Ronny Stolz^d and Andreas Chwala^e
View Affiliations Hide Affiliations

^a Intrepid Geophysics, Brighton, Victoria, , Australia, [email protected] ^b Intrepid Geophysics, Brighton, Victoria, , Australia, [email protected] ^c University of Aberystwyth Aberystwyth, , Wales, , UK, [email protected] ^d Institute for Physical High-Technology, Jena, , Germany, [email protected] ^e Institute for Physical High-Technology, Jena, , Germany, [email protected]
Publisher: Australian Society of Exploration Geophysicists
Source: ASEG Extended Abstracts, Volume 2010, Issue ASEG2010 - 21st Geophysical Conference, Dec 2010, p. 1 - 4
DOI: https://doi.org/10.1081/22020586.2010.12042011
- Published online: 01 Dec 2010

Abstract

Summary

In recent developments a full tensor magnetic gradient system has been deployed in South Africa. The instrument is made by IPHT (Institute of Photonic Technology, Jena, Germany) and flown by helicopter. In developing a ‘custom’ solution for taking the raw signal through to a final located geophysically sound data base, one of the biggest challenges has proven to be the compensation of aircraft / bird rotational movements, so that the reported magnetic curvature gradients in the world co-ordinate system are as free of these rotational errors as possible.

Issues that arise include drift correction of the Euler Angles from the INS (Inertial Navigation System), removal of flux jumps from the SQUID and recovering the three components of the ‘B’ field.

Compensation issues are limiting the achievable resolution of the field gradients.

A novel least-squares rotational adjustment of the tensor signal in a moving window is proposed as an extra compensation step to achieve higher spatial coherency of the curvature gradients.

Article metrics loading...

/content/journals/10.1081/22020586.2010.12042011

2010-12-01

2026-01-17

From This Site

/content/journals/10.1081/22020586.2010.12042011

dcterms_title,dcterms_subject,pub_keyword

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

10

5

Full text loading...

References

Crassidis, J., 2005, Intregrated GPS and inertial navigation: AIAA-2005-6052
FitzGerald, D., Argast, D, Paterson, R., Holstein, H., 2009, Full Tensor Magnetic Gradiometry Processing and Intrepretation Developments: 11th SAGA Conference.
Hardwick, C., 1984, Important design considerations for inboard airborne magnetic gradiometers: Geophysics 49
Jia, J., Lo, R., Groom, R., 2004, A new aircraft compensation system for magnetic terrains. Final report on improved aeromagnetic compensation: OMET Program Report #P02-03-043, 70p.
Leliak P., 1961, Identification and evaluation of magnetic field sources of magnetic airborne detector MAD equipped aircraft: IRA Transactions on airspace and navigational electronics, Volume 8, P.95-105
Rompel A., 2009 Geological applications of FTGM: 11th SAGA conference.
Stolz R., Zakosarenko V., Schulz M., et al., Magnetic fulltensor SQUID gradiometer system for geophysical applications: 2006, The Leading Edge, Volume 25, No 2, P. 178-180
Stolz R., 2009, Magnetic full tensor gradiometry: 11th SAGA conference

/content/journals/10.1081/22020586.2010.12042011

Article Type: Research Article

Keyword(s): Euler angles; INS; quaternions; tensor gradients

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 Compensation of the full magnetic tensor gradient signal

Abstract

Most Read This Month

Most Cited This Month Most Cited RSS feed