NATURAL SMOOTHNESS CONSTRAINTS IN CROSS‐HOLE SEISMIC TOMOGRAPHY1

M. PILKINGTON; J. P. TODOESCHUCK

doi:10.1111/j.1365-2478.1992.tb00373.x

E-ISSN: 1365-2478

NATURAL SMOOTHNESS CONSTRAINTS IN CROSS‐HOLE SEISMIC TOMOGRAPHY¹
Authors M. PILKINGTON¹, J. P. TODOESCHUCK^2,3
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Affiliations: ¹ Geophysics Division, Geological Survey of Canada, 1 Observatory Crescent, Ottawa, Ont., Canada K1A 0Y3. ² Defence Research Establishment Pacific, FMO Victoria, B.C., Canada VOS 1B0.

3 fn2I.C.I. Explosives Canada, 801 Richelieu Boulevard, McMasterville, Que., Canada JG 1T9.
Source: Geophysical Prospecting, Volume 40, Issue 2, Mar 1992, p. 227 - 242
DOI: https://doi.org/10.1111/j.1365-2478.1992.tb00373.x
- Published online: 27 Apr 2006

Abstract

Tomographic inversion problems are ill‐posed and therefore solutions must be either damped or regularized to produce results that are geologically reasonable. We introduce a priori information in terms of parameter covariances to constrain the solution. We use slowness logs to determine the appropriate parameter covariances for the inversion of traveltime data collected for a cross‐hole geometry. We find that the logs exhibit power spectra proportional to a power α of the frequency. The value of α controls the smoothness of the inversion solution. For α < 0, the solution smoothness is maximized. Thus, knowing the correct value of α, which can be found from well logs, we can specify the appropriate amount of smoothing, rather than using some arbitrary level.

Inversions were carried out on synthetic data for the case of α= 0 and α=−1. The use of α= 0 implies uncorrelated model parameters and is equivalent to standard damped least‐squares methods. We find that solutions for α= 0 show greater complexity than for α=−1 but this level of resolution can be illusory. An example from the Midale field, Saskatchewan, Canada, is inverted using both α= 0 and α=−2, given by the observed parameter covariances. The solution for α= 0 exhibits spurious detail which must be smoothed away. For α=−2, the solution smoothness is maximized and we recover only that structure which is required to fit the data.

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References

Abdalla, A.A., Stewart, R.R. and Henley, D.C.1990. Traveltime inversion and reflection processing of cross‐hole seismic data. 60th SEG meeting, San Francisco, U.S.A., Expanded Abstracts, 47–50.
Constable, S.C., Parker, R.L. and Constable, C.G.1987. Occam's inversion: a practical algorithm for generating smooth models from electromagnetic sounding data. Geophysics52, 289–300.
[Google Scholar]
Dines, K.A. and Lytle, R.J.1979. Computerized geophysical tomography. Proceedings of the IEEE67, 1065–1073.
[Google Scholar]
Flatte, S.M. and Wu, R.S.1988. Small scale structure in the lithosphere and asthenosphere deduced from arrival time and amplitude fluctuations at NORSAR. Journal of Geophysical Research93, 6601–6614.
[Google Scholar]
Frankel, A. and Clayton, R.1986. Finite difference simulation of seismic scattering: implications for the propagation of short‐period seismic waves in the crust and models of crustal heterogeneity. Journal of Geophysical Research91, 6465–6489.
[Google Scholar]
Franklin, J.N.1970. Well‐posed stochastic extensions of ill‐posed linear problems. Journal of Mathematical Analysis and Applications31, 682–716.
[Google Scholar]
Gersztenkorn, A. and Scales, J.A.1988. Smoothing seismic tomograms with alpha‐trimmed means. Geophysical Journal of the Royal Astronomical Society92, 67–72.
[Google Scholar]
Golub, G.H., Heath, M. and Wahba, G.1979. Generalized cross‐validation as a method for choosing a good ridge parameter. Technometrics21, 215–223.
[Google Scholar]
Gregotski, M.E., Jensen, O.G. and Arkani‐Hamed, J.1991. Fractal stochastic modeling of aeromagnetic data. Geophysics56, 1706–1715.
[Google Scholar]
Hosken, J.W.J.1981. A stochastic model of seismic reflections. Geophysics46, 419.
[Google Scholar]
A.Vogel
Ilk, K.H.1988. A proposal for the determination of optimal regularization parameters in Tikhonov‐type regularization methods. In: Model Optimization in Exploration Geophysics. A.Vogel (ed.), 65–87. Vieweg.
[Google Scholar]
Jackson, D.D.1979. The use of a priori data to resolve non‐uniqueness in linear inversion. Geophysical Journal of the Royal Astronomical Society57, 137–158.
[Google Scholar]
Jordan, T.H. and Franklin, J.N.1971. Optimal solutions to a linear inverse problem in geophysics. Proceedings of the National Academy of Sciences68, 291–293.
[Google Scholar]
Kanasewich, E.R.1981. Time Sequence Analysis in Geophysics. University of Alberta Press.
[Google Scholar]
Mandelbrot, B.B.1983. The Fractal Geometry of Nature. W. H. Freeman & Co.
[Google Scholar]
Marquardt, D.W.1963. An algorithm for least squares estimation of nonlinear parameters. Journal of the Society of Industrial and Applied Mathematics11, 431–441.
[Google Scholar]
McGaughey, W.J. and Young, R.P.1990. Comparison of ART, SIRT, least‐squares, and SVD two‐dimensional tomographic inversions of field data. 60th SEG meeting, San Francisco, U.S.A., Expanded Abstracts, 74–77.
Meyerholtz, K.A., Pavlis, G.L. and Szpakowski, S.A.1989. Convolutional quelling in seismic tomography. Geophysics54, 570–580.
[Google Scholar]
Montagner, J.‐P. and Jobert, N.1988. Vectorial tomography. II. Application to the Indian Ocean. Geophysical Journal of the Royal Astronomical Society94, 309–344.
[Google Scholar]
Nercessian, A., Hirn, A. and Tarantola, A.1984. Three‐dimensional seismic prospecting of the Monte Dore volcano, France. Geophysical Journal of the Royal Astronomical Society76, 307–315.
[Google Scholar]
Parker, R.L. and Shure, L.1982. Efficient modelling of the Earth's magnetic field with harmonic splines. Geophysical Research Letters9, 812–815.
[Google Scholar]
Pilkington, M. and Todoeschuck, J.P.1989. Power spectral characteristics of geophysical well logs. EOS Transactions, American Geophysical Union70, 476.
[Google Scholar]
Pilkington, M. and Todoeschuck, J.P.1990. Stochastic inversion for scaling geology. Geophysical Journal International102, 205–217.
[Google Scholar]
Pilkington, M. and Todoeschuck, J.P.1991. Naturally smooth inversions with a priori information from well‐logs. Geophysics56, 1811–1818.
[Google Scholar]
Rodgers, C.D.1976. Retrieval of atmospheric temperature and composition from remote measurements of thermal radiation. Reviews of Geophysics and Space Physics14, 609–624.
[Google Scholar]
Sambridge, M.S.1990. Non‐linear arrival time inversion: constraining velocity anomalies by seeking smooth models in 3‐D. Geophysical Journal International102, 653–677.
[Google Scholar]
Scales, J.A. and Gersztenkorn, A.1988. Robust methods in inverse theory. Inverse Problems4, 1071–1091.
[Google Scholar]
Tarantola, A. and Valette, B.1982a. Inverse problems = Quest for information. Journal of Geophysics50, 159–170.
[Google Scholar]
Tarantola, A. and Valette, B.1982b. Generalized nonlinear inverse problems solved using the least squares criterion. Reviews of Geophysics and Space Physics20, 219–232.
[Google Scholar]
Tikhonov, A.N.1963. Resolution of ill‐posed problems and the regularization method. Doklady Akademii Nauk SSSR151, 501–504.
[Google Scholar]
Todoeschuck, J.P. and Jensen, O.G.1988. Joseph geology and seismic deconvolution. Geophysics53, 1410–1414.
[Google Scholar]
Todoeschuck, J.P. and Jensen, O.G.1989. Scaling geology and seismic deconvolution. Pure and Applied Geophysics131, 273–288.
[Google Scholar]
Todoeschuk, J.P., Jensen, O.G. and Labonte, S.1990. Gaussian scaling noise model of seismic reflection sequences: evidence from well logs. Geophysics55, 480–484.
[Google Scholar]
Twomey, S.1977. Introduction to the Mathematics of Inversion in Remote Sensing and Indirect Measurements. Elsevier Science Publishing Co.
[Google Scholar]
Walden, A.T. and Hosken, J.W.J.1985. An investigation of the spectral properties of primary reflection coefficients. Geophysical Prospecting33, 400–435.
[Google Scholar]
Wiggins, R.A.1972. The general linear inverse problem: implication of surface waves and free oscillations for Earth structure. Reviews of Geophysics and Space Physics10, 251–285.
[Google Scholar]

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NATURAL SMOOTHNESS CONSTRAINTS IN CROSS‐HOLE SEISMIC TOMOGRAPHY¹

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