A comparison of seven geostatistically based inverse approaches to estimate transmissivities for modeling advective transport by groundwater flow

Zimmerman, D.A.; Marsily, Ghislain de; Gotway, Carol A.; Marietta, M.G.; Axness, Carl L.; Beauheim, Richard L.; Bras, Rafael L.; Carrera, Jesús; Dagan, Gédéon; Davies, Philip; Gallegos, D.P.; Galli, Alain; Gómez‐Hernández, J. Jaime; Grindrod, Peter; Gutjahr, Allan L.; Kitanidis, Peter K.; LaVenue, A.M.; McLaughlin, Dennis K.; Neuman, S. P.; RamaRao, Banda S.; Ravenne, C.; Rubin, Yoram

doi:10.1029/98wr00003

Cited by 299 publications

(192 citation statements)

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“…Each realization derived in this way requires O d 2 N f computations. This can be considerably more e cient than alternative conditional simulation methods (such as those described in [19]), even when the log conductivity ®eld is Gauss±Markov and d is O N 0X5 f . The travel time example discussed in the next section illustrates both the estimation and conditional simulation aspects of the multiscale approach.…”

Section: Vsy Rxmentioning

confidence: 99%

“…The travel times of wastes released from underground storage facilities to the accessible environment provide valuable information for assessing possible exposure risks. Travel time is particularly important in radioactive waste disposal applications, since the exposure level for any given constituent depends on the ratio of travel time to halflife [19]. When the factors controlling solute transport are highly variable and uncertain it is best to use probabilistic approaches to characterize travel times and related risks.…”

Section: The Travel Time Estimation Problemmentioning

confidence: 99%

“…As an example, we describe a multiscale algorithm which estimates groundwater travel times and generates travel time probability distributions. Our example is a simpli®ed version of the waste isolation performance assessment problem considered in a recent comparison of popular groundwater inverse procedures [19]. In the remaining sections of this paper we review relevant multiscale estimation concepts, describe the travel time estimation problem, and present some typical results.…”

Section: Introductionmentioning

confidence: 99%

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A multiscale approach for estimating solute travel time distributions

Daniel

Willsky

McLaughlin

2000

Advances in Water Resources

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This paper uses a multiscale statistical framework to estimate groundwater travel times and to derive conditional travel time probability densities. In the applications of interest here travel time uncertainties depend primarily on uncertainties in hydraulic conductivity. These uncertainties can be reduced if the travel times are conditioned on scattered measurements of hydraulic conductivity and/or hydraulic head. In our approach the spatially discretized log hydraulic conductivity is modeled as a multiscale stochastic process, where each scale describes the process at a di erent spatial resolution. Related dependent variables such as hydraulic head and travel time are approximated by discrete linear functions of the log conductivity. The linearization makes it possible to incorporate these variables into e cient multiscale estimation and conditional simulation algorithms. We illustrate the application of these algorithms by considering two options for estimating travel time densities: (1) a Monte Carlo technique which only requires linearization of the groundwater¯ow equation and (2) a Gaussian approximation which also requires linearization of Darcy's law and an implicit particle tracking equation. Both options provide reasonable estimates of the travel time probability density in a synthetic experiment if the underlying log hydraulic conductivity variance is small (0.5). When this variance is increased (to 5.0), the Monte Carlo result is still quite good but the Gaussian approximation is unsatisfactory. The multiscale Monte Carlo option is a very competitive approach for estimating travel time since it provides accurate results over a wide range of conditions and it is more computationally e cient than competing alternatives. Ó

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Section: Vsy Rxmentioning

confidence: 99%

Section: The Travel Time Estimation Problemmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A multiscale approach for estimating solute travel time distributions

Daniel

Willsky

McLaughlin

2000

Advances in Water Resources

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“…The procedures commonly used range from ad hoc trial-and-error methods to sophisticated mathematical/statistical inverse algorithms. In a recent and exhaustive study comparing seven inverse approaches to estimate parameters for flow and solute transport models (Zimmerman et al, 1998), the authors concluded that "…the most important factor for achieving a successful solution was the time and experience devoted by the user of the method". This underlines an important point that applies not only to inverse methods, but more importantly to groundwater models themselves: Comprehensive physically-based numerical models are powerful tools, and are increasingly being equipped with user-friendly graphical interfaces and instant post-processing utilities (plots, maps, summary reports, etc), but their proper use for analysis and decision support will continue to require on the part of the user some knowledge of the underlying processes and their interactions, of the mathematical representation of these processes via equations and parameters, and of the particular features of the computer implementation -these are elements that can make the difference between a successful simulation and a meaningless one.…”

Section: Parameter Estimation and Model Calibrationmentioning

confidence: 99%

Agricultural Impacts on Groundwater: Processes, Modelling and Decision Support

Giacomelli¹,

Giupponi²,

Paniconi³

2001

Agricultural Use of Groundwater

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“…Numerous methods are able to work with a variety of data and model types in hydrology, meteorology, and oceanography such as those in Kitanidis and Vomvoris 1983, Hoeksema and Kitinidis 1984, Dagan 1985, Gelhar 1986 Neuman 1986a;b;c , Ghil 1989, Carrera and Glorioso 1991 , Yangxiao et al 1991, Bennett 1992, Sun and Yeh 1992, Courtier et al 1993 Daniel andWillsky 1997 andZimmerman et al 1998 . Many of the crucial issues in moving from theory to practice are well understood.…”

Section: Introductionmentioning

confidence: 99%