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A series expansion approach to the inverse problem

Part of: Stochastic analysis Stochastic processes

Published online by Cambridge University Press:  14 July 2016

J. M. Angulo  and
M. D. Ruiz-Medina
J. M. Angulo*
Affiliation:
Universidad de Granada
M. D. Ruiz-Medina*
Affiliation:
Universidad de Granada
*
Postal address: Departamento de Estadística e I.O. Universidad de Granada, Campus de Fuentenueva s/n, E-18071 Granada, Spain.
Postal address: Departamento de Estadística e I.O. Universidad de Granada, Campus de Fuentenueva s/n, E-18071 Granada, Spain.
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Abstract

We consider the inverse problem of estimating the input random field in a stochastic integral equation relating two random fields. The purpose of this paper is to present an approach to this problem using a Riesz-based or orthonormal-based series expansion of the input random field with uncorrelated random coefficients. We establish conditions under which the input series expansion induces (via the integral equation) a Riesz-based or orthonormal-based series expansion for the output random field. The estimation problem is studied considering two cases, depending on whether data are available from either the output random field alone, or from both the input and output random fields. Finally, we discuss this approach in the case of transmissivity estimation from piezometric head data, which was the original motivation of this work.

Keywords

Linear predictionmean-square convergenceorthonormal-based series expansionRiesz-based series expansionthe inverse problem

MSC classification

Primary: 60G60: Random fields 60G12: General second-order processes
Secondary: 60G25: Prediction theory 60H15: Stochastic partial differential equations
Type
Research Papers
Information
Journal of Applied Probability , Volume 35 , Issue 2 , June 1998 , pp. 371 - 382
Copyright
Copyright © Applied Probability Trust 1998 

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References

Angulo, J.M., and Ruiz-Medina, M.D. (1995a). On existence conditions for orthogonal representation of unbounded parameter space random fields. Technical Report, Department of Statistics and Operation Research, University of Granada (Spain).Google Scholar
Angulo, J.M., and Ruiz-Medina, M.D. (1995b). Una aproximación alternativa al problema de estimación de transmisividades. In Proc. XXII Congreso Nacional de Estadística e I.O., Sevilla, Spain, pp. 78.Google Scholar
Angulo, J.M., and Ruiz-Medina, M.D. (1996). Karhunen–Loève and wavelet approximations to the inverse problem. In Proc. Computational Statistics (COMPSTAT 1996, Barcelona), ed. Prat, A. Physica-Verlag, Heidelberg, pp. 187192.Google Scholar
Dagan, G. (1985). Stochastic modelling of groundwater flow by unconditional and conditional probabilities: The inverse problem. Water Resources Res. 21, 6572.Google Scholar
Dietrich, C.D., Ghassemi, F., and Jakeman, A.J. (1986). An inverse problem in aquifer parameter identification. In Proc. of the Centre for Mathematical Analysis 11: Workshop on inverse problems, eds Anderssen, R.S. and Newsam, G.N. Centre for Mathematical Analysis, ANU, Canberra.Google Scholar
Dietrich, C.D., and Newsam, G.N. (1989). A stability analysis of the geostatistical approach to aquifer transmissivity identification. Stochastic Hydrol. Hydraul. 3, 293316.Google Scholar
Hoeksema, R.J., and Kitanidis, P.K. (1984). An application of the geostatistical approach to the inverse problem in two-dimensional groundwater modelling. Water Resources Res. 20, 10031020.Google Scholar
Hoeksema, R.J., and Kitanidis, P.K. (1985). Comparison of Gaussian conditional mean and kriging estimation in the geostatistical solution of the inverse problem. Water Resources Res. 21, 825836.Google Scholar
Hutson, V., and Pym, J.S. (1980). Applications of Functional Analysis and Operator Theory. Academic Press, London.Google Scholar
Kitanidis, P.K., and Vomvoris, E.G. (1983). A geostatistical approach to the inverse problem in groundwater modelling (steady state) and one-dimensional simulation. Water Resources Res. 19, 677690.Google Scholar
Kuiper, L.K. (1986). A comparison of several methods for the solution of inverse problem in two-dimensional steady state groundwater flow modelling, Water Resources Res. 22, 705714.Google Scholar
Meyer, Y. (1992). Wavelets and Operators. Cambridge University Press.Google Scholar
Roach, G.F. (1982). Green's Functions, 2nd edn. Cambridge University Press, London.Google Scholar
Rubin, Y., and Dagan, G. (1987). Stochastic identification of transmissivity and effective recharge in steady groundwater flow. 1: Theory. Water Resources Res. 23, 11851192.Google Scholar
Rubin, Y., and Dagan, G. (1988). Stochastic analysis of boundaries effects on head spatial variability in heterogeneous aquifers. 1: Constant head boundary. Water Resources Res. 24, 16891697.Google Scholar
Ruiz-Medina, M.D., and Valderrama, M.J. (1996). Orthogonal representation of random fields and an application of geophysics data. J. Appl. Prob. 34, 458476.Google Scholar
Yosida, K. (1980). Functional Analysis, 6th edn. Springer-Verlag, New York.Google Scholar
Zhang, J., and Walter, G. (1994). A wavelet-based KL-like expansion for wide-sense stationary random processes. IEEE Trans. Signal Processing 42, 17371744.Google Scholar