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RESEARCH ARTICLE
Contents Vol 39(4)

Practical aspects of terrain correction in airborne gravity gradiometry surveys*

M. Andy Kass 1 2 Yaoguo Li 1
+ Author Affiliations
- Author Affiliations

1 Center for Gravity, Electrical, and Magnetic Studies, Department of Geophysics, Colorado School of Mines, 1500 Illinois Street, Golden, Colorado 80401, USA.

2 Corresponding author. Email: mkass@mines.edu

Exploration Geophysics 39(4) 198-203 https://doi.org/10.1071/EG08021
Submitted: 17 February 2008  Published: 15 December 2008

Abstract

Proper terrain correction in onshore airborne gravity gradiometry surveys requires detailed digital elevation models (DEMs). However, the horizontal resolution requirement of DEMs is not well explored in literature. As a result, there is no standardized horizontal resolution used in commercial surveys. Also, the effect of requisite low-pass filtering applied during and subsequent to acquisition has not been discussed within this context. We address these issues by quantifying the optimal horizontal resolution using an example dataset and a practical method for performing terrain corrections in barometric surveys, based on Parker’s 1972 Fourier-domain calculation. We also quantify the required spatial extents of DEMs (including grid padding) by deriving empirical rules based on numerical simulations. With these parameters quantified, we provide the basis for optimising the terrain correction to improve efficiency in not only gravity gradiometry terrain corrections and forward modelling, but also in DEM acquisition survey design.

Key words: DEM resolution, gravity gradiometry, terrain correction.


Acknowledgments

We thank Misac Nabighian for his valuable insight. We also thank Jeongmin Lee and Korea Resources Corporation for the partial funding support and Sky Research, Inc. for the LiDAR data. This work is also partly supported by the Gravity and Magnetics Research Consortium (GMRC), a part of the Center for Gravity, Electrical, and Magnetic Studies (CGEM) at the Colorado School of Mines. The authors would like to recognise the outstanding efforts of the anonymous reviewers of this paper.


References

Chen, J., and Macnae, J. C., 1997, Terrain corrections are critical for airborne gravity gradiometer data: Exploration Geophysics 28, 21–25.
Crossref | GoogleScholarGoogle Scholar | Lane R. , 2004, Integrating ground and airborne data into regional gravity compilations: Airborne Gravity 2004 – ASEG-PESA Airborne Gravity 2004 Workshop, 81–97.

Lee J. , 2006, Effects of low-pass filtering on inversion of airborne gravity gradient data: M. S. thesis, Colorado School of Mines: Golden, Colorado, USA.

Parker, R. L., 1972, The rapid calculation of potential anomalies: Geophysical Journal of the Royal Astronomical Society 31, 447–455.


Parker, R. L., 1995, Improved Fourier terrain correction, Part I: Geophysics 60, 1007–1017.
Crossref | GoogleScholarGoogle Scholar |

Parker, R. L., 1996, Improved Fourier terrain correction, Part II: Geophysics 61, 365–372.
Crossref | GoogleScholarGoogle Scholar |

Pawlowski, B., 1998, Gravity gradiometry in resource exploration: Leading Edge 17, 51–52.
Crossref | GoogleScholarGoogle Scholar |

Tziavos, I. N., Sideris, M. G., Forsberg, R., and Schwarz, K. P., 1988, The effect of the terrain on airborne gravity and gradiometry: Journal of Geophysical Research 93, 9173–9186.
Crossref | GoogleScholarGoogle Scholar |




*Presented at the 19th ASEG Geophysical Conference & Exhibition, November 2007.