A comparison between Laplace domain and frequency domain methods for inverting seismic waveforms

Wansoo Ha; YoungHo Cha; Changsoo Shin

doi:10.1071/EG09031

RESEARCH ARTICLE

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A comparison between Laplace domain and frequency domain methods for inverting seismic waveforms

Wansoo Ha ¹ ³ YoungHo Cha ² Changsoo Shin ¹

+ Author Affiliations

- Author Affiliations

¹ Department of Energy System Engineering, Seoul National University, San 56-1, Shillim-dong, Gwanak-gu, Seoul 151-742, South Korea.

² Present address: ExxonMobil Upstream Research Company, 3120 Buffalo Speedway, Houston, TX 77098, USA.

³ Corresponding author. Email: plusha@gpl.snu.ac.kr

Exploration Geophysics 41(3) 189-197 https://doi.org/10.1071/EG09031
Submitted: 15 July 2009 Accepted: 16 July 2010 Published: 15 September 2010

Abstract

We compared the ability of full waveform inversion to recover background velocity models from data containing no low-frequency information using the frequency and Laplace domains. Low-frequency information is crucial for recovering background velocity when using frequency-domain waveform inversions. However, the dearth of low-frequency information in field data makes frequency-domain inversion impractical without accurate starting velocity models. Instead, by performing waveform inversion in the Laplace domain, one can recover a smooth velocity model that can be used for either migration or for subsequent frequency-domain inversion as an accurate initial velocity model. The Laplace-transformed wavefield can be thought of as the zero-frequency component of a damped wavefield over a range of damping constants. In this paper, we compare results obtained from both frequency- and Laplace-domain inversions and confirm that the Laplace-domain inversion can be used to recover background velocity from real data without low-frequency information. We also demonstrate that the Laplace-domain inversion can provide the frequency-domain inversion with smooth initial velocity models for better inversion results.

Key words: acoustic, frequency domain, Laplace domain, smooth velocity model, waveform inversion.

Acknowledgments

This work was supported by the Brain Korea 21 project of the Ministry of Education. We are grateful to GX Technology for providing us with the field datasets.

References

Aki K. , and Richards P. G. , 2002, Quantitative seismology, 2nd edn: University Science Books.

Amundsen, L., 1991, Comparison of the least-squares criterion and the Cauchy criterion in frequency-wavenumber inversion: Geophysics 56, 2027–2035.
| Crossref | GoogleScholarGoogle Scholar | Gray S.H. , 2000, Velocity smoothing for depth migration: how much is too much?: 70th Annual International Meeting, SEG, 1055–1058.

Guitton, A., and Symes, W., 2003, Robust inversion of seismic data using the Huber norm: Geophysics 68, 1310–1319.
| Crossref | GoogleScholarGoogle Scholar | Kolb P. , Collino F. , and Lailly P. , 1986, Prestack inversion of a 1D medium: Proceedings of the Institute of Electrical and Electronics Engineers, Inc., 74, 498–506.

Lailly P. , 1983, The seismic inverse problem as a sequence of before stack migration. Conference on inverse scattering: Theory and Application: Society for Industrial and Applied Mathematics.

Marfurt, K. J., 1984, Accuracy of finite-difference and finite-element modeling of the scalar and elastic wave equation: Geophysics 49, 533–549.
| Crossref | GoogleScholarGoogle Scholar | Pacheco C. , and Larner K. , 2005, Velocity smoothing before depth migration: Does it help or hurt?: 75th Annual International Meeting, SEG, 1970–1973.

Pratt, R. G., 1999, Seismic waveform inversion in frequency domain, Part 1: Theory and verification in physical scale model: Geophysics 64, 888–901.
| Crossref | GoogleScholarGoogle Scholar | Zienkiewicz O. C. , and Taylor R. L. , 1991, The finite element method, 4/e Vol II: McGraw Hill Book Co.