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Hydrogeology Journal

Erschienen in:

01.05.2015 | Paper

Functional parameterization for hydraulic conductivity inversion with uncertainty quantification

verfasst von: Jianying Jiao, Ye Zhang

Erschienen in: Hydrogeology Journal | Ausgabe 3/2015

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Abstract

Functional inversion based on local approximate solutions (LAS) is developed for steady-state flow in heterogeneous aquifers. The method employs a set of LAS of flow to impose spatial continuity of hydraulic head and Darcy fluxes in the solution domain, which are conditioned to limited measurements. Hydraulic conductivity is first parameterized as piecewise continuous, which requires the addition of a smoothness constraint to reduce inversion artifacts. Alternatively, it is formulated as piecewise constant, for which the smoothness constraint is not required, but the data requirement is much higher. Success of the inversion with both parameterizations is demonstrated for both one-dimensional synthetic examples and an oil-field permeability profile. When measurement errors are increased, estimation becomes less accurate but the solution is stable, i.e., estimation errors remain bounded. Compared to piecewise constant parameterization, piecewise continuous parameterization leads to more stable and accurate inversion. Moreover, conductivity variation can also be captured at two spatial scales reflecting sub-facies smooth-varying heterogeneity as well as abrupt changes at facies boundaries. By combining inversion with geostatistical simulation, uncertainty in the estimated conductivity and the hydraulic head field can be quantified. For a given measurement dataset, inversion accuracy and estimation uncertainty with the piecewise continuous parameterization is not sensitive to increasing conductivity contrast.

Vorheriger Artikel Assessment of well vulnerability for groundwater source protection based on a solute transport model: a case study from Jilin City, northeast China

Nächster Artikel Erratum: Recharge mixing in a complex distributary spring system in the Missouri Ozarks, USA

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Anderson MP (1997) Characterization of geological heterogeneity. In: Subsurface flow and transport: a stochastic approach. Cambridge University Press, Cambridge, UK, pp 23–43

Amudo C, Graf T, Harris NR, Dandekar R, Amor FB, May R S (2008) Experimental design and response surface models as a basis for stochastic history matching: a Niger Delta experience. SPE paper no. 12665, SPE, Richardson, TX

Capilla JE, Rodrigo J, Gomez-Hernandez JJ (1999) Simulation of non-Gaussian transmissivity fields honoring piezometric data and integrating soft and secondary information. Math Geol 31(7):907–927CrossRef

Carrera JY, Neuman SP (1986a) Estimation of aquifer parameters under steady-state and transient conditions: I. background and statistical framework. Water Resour Res 22(2):199–210CrossRef

Carrera JY, Neuman SP (1986b) Estimation of aquifer parameters under steady-state and transient conditions: II. uniqueness, stability, and solution algorithms. Water Resour Res 22(2):211–227CrossRef

Carrera JY, Neuman SP (1986c) Estimation of aquifer parameters under steady-state and transient conditions: III. applications. Water Resour Res 22(2):228–242CrossRef

Carrera J, Alcolea A, Medina A, Hidalgo J, Slooten LJ (2005) Inverse problem in hydrogeology. Hydrogeol J 13:206–222CrossRef

Deutsch CV, Journel AG (1994) Integrating well test-derived effective absolute permeabilities in geostatistical reservoir modeling. In: Yarus JM, Chambers RL (eds) Stochastic modeling and geostatistics, vol 3. AAPG, Tulsa, OK, pp 131–142

Doherty J (2005) PEST: Software for model-independent parameter estimation, Watermark Numerical Computing, Brisbane, Australia. http://www.pesthomepage.org/Home.php. Accessed October 2013.

Eide A L, Holden L, Reiso E, Aanonsen SI (1994) Automatic history-matching by use of response surfaces and experimental design. Proceedings, 4th European Conference on the Mathematics of Oil Recovery, Roros, Norway, June 1994

Eppstein MJ, Dougherty DE (1996) Simultaneous estimation of transmissivity values and zonation. Water Resour Res 32(11):3321–3336CrossRef

Ferraresi M, Todini E, Vignoli R (1996) A solution to the inverse problem in groundwater hydrology based on Kalman filtering. J Hydrol 175:567–581CrossRef

Fogg GE (1990) Architecture and interconnectedness of geologic media: role of the low-permeability facies in flow and transport. Heise, Hannover, Germany, pp 19–40

Gallo YL, Ravalec-Dupin ML (2000) History matching geostatistical reservoir models with gradual deformation method. Proceedings, 1st International Energy Agency Workshop and Symposium, Edinburgh, UK, September 20–22, 2000

Gelhar LW (1992) Stochastic subsurface hydrology, Prentice Hall, Upper Saddle River, NJ, 480 pp

Ginn TR, Cushman JH (1990) Inverse methods for subsurface flow: a critical review of stochastic techniques. Stoch Hydrol Hydraul 4(1):1–26CrossRef

Hill MC (1992) A computer program (MODFLOWP) for estimating parameters of a transient, three dimensional, groundwater flow model using nonlinear regression. US Geol Surv Open File Rep 91-484

Hill MC, Tiedeman CR (2007) Effective groundwater model calibration: with analysis of data, sensitivities, predictions, and uncertainty. Wiley, New York, 480 pp

Irsa J, Zhang Y (2012) A new direct method of parameter estimation for steady state flow in heterogeneous aquifers with unknown boundary conditions. Water Resour Res 48, W09526. doi:10.1029/2011WR011,756

Janssen GMCM, Valstar JR, Sjoerd EA, van der Zee TM (2006) Inverse modeling of multimodal conductivity distributions. Water Resour Res 42, W03410. doi:10.1029/2005WR004356

Jiao JY, Zhang Y (2014a) Two-dimensional inversion of confined and unconfined aquifers under unknown boundary condition. Adv Water Resour 65:43–57CrossRef

Jiao JY, Zhang Y (2014b) Tensor hydraulic conductivity estimation for heterogeneous aquifers under unknown boundary conditions. Groundwater. doi:10.1111/gwat.12202

Jiao JY, Zhang Y (2014c) A method based on Local Approximate Solutions (LAS) for inverting transient flow in heterogeneous aquifers. J Hydrol. doi10.1016/j.hydrol.2014.04.004

Kitanidis PK (1995) Quasi-linear geostatistical theory for inversing. Water Resour Res 31(10):2411–2419CrossRef

Kromah MJ, Liou J, MacDonald DG (2005) Step change in reservoir simulation breathes life into mature oil field. SPE paper no. 94940, SPE, Richardson, TX

Labaky W, Devlin JF, Gillham RW (2009) Field comparison of the point velocity probe with other groundwater velocity measurement method. Water Resour Res 45, W00D30. doi:10.1029/2008WR007066 CrossRef

LaVenue AM, Pickens JF (1992) Application of a coupled adjoint sensitivity and kriging approach to calibrate a groundwater model. Water Resour Res 28(6):1543–1570CrossRef

McLaughlin D, Townley LR (1996) A reassessment of the groundwater inverse problem. Water Resour Res 32(5):1131–1161CrossRef

McKenna SA, Poeter EP (1995) Field example of data fusion in site characterization. Water Resour Res 31(12):3229–3240CrossRef

Medina A, Carrera J (2003) Geostatistical inversion of coupled problems: dealing with computational burden and different type of data. J Hydrol 281(4):251–264CrossRef

Poeter EP, Hill MC, Banta ER, Mehl S, Christensen S (2005) UCODE_2005 and six other computer codes for universal sensitivity analysis, calibration, and uncertainty evaluation. USGS Techniques and Methods, 6-A11, USGS, Reston, VA, 283 pp

Porter DW, Gibbs BP, Jones WF, Huyakorn PS, Hamm LL, Flach GP (2000) Data fusion modeling for groundwater systems. J Contam Hydrol 42:303–335CrossRef

Post VEA, von Asmuth JR (2013) Review: hydraulic head measurements: new technologies, classic pitfalls. Hydrogeol J 21:737–750CrossRef

Ramanathan R, Guin A, Ritzi RW et al (2010) Simulating the heterogeneity in braided channel belt deposits: 1. a geometric‐based methodology and code. Water Resour Res 46(4), W04515. doi:10.1029/2009WR008111

Rogers SJ, Chen HC, Kopaska-Merkel DC, Fang JH (1995) Predicting permeability from porosity using artificial neural networks. AAPG Bull 79(12):1786–1796

Roggero F, Hu LY (1998) Gradual deformation of continuous geostatistical models for history matching. SPE paper no. 49005, SPE, Richardson, TX

Romero CE, Carter JN, Zimmermann RW, Gringarten AC (2000) Improved reservoir characterization through evolutionary computation. SPE paper no. 62942, SPE, Richardson, TX

Sagar B, Yakowitz S, Duckstein L (1975) A direct method for the identification of the parameters of dynamic nonhomogeneous aquifers. Water Resour Res 11(4):563–570. doi:10.1029/WR011i004p00563 CrossRef

Sakaki T, Frippiat CC, Komatsu M, Illangasekare TH (2009) On the value of lithofacies data for improving groundwater flow model accuracy in a three-dimensional laboratory-scale synthetic aquifer. Water Resour Res 45, W11404. doi:10.1029/2008WR007229

Scheibe DT, Freyberg DL (1995) Use of sedimentological information for geometric simulation of natural porous media structure. Water Resour Res 31:3259–3270CrossRef

Schulze-Riegert R, Axmann J, Haase O, Rian D, You Y (2002) Evolutionary algorithms applied to history matching of complex reservoirs. SPE Reserv Eval Eng 5(2):163–173CrossRef

Tartakovsky DM (2013) Assessment and management of risk in subsurface hydrology: a review and perspective. Adv Water Resour 51:247–260CrossRef

Vrugt JA, Stauffer PH, Wohling T, Robinson BA, Vesselinov VV (2008) Inverse modeling of subsurface flow and transport properties: a review with new developments. Vadose Zone J 7:843–864CrossRef

Wen XH, Deutsch CV, Cullick AS, Reza ZA (2000) Integration of production data in generating reservoir models. Stanf Cent For Comput Geostat (CCG) Monogr Ser 1:205

Yeh WWG (1986) Review of parameter identification procedures in groundwater hydrology: the inverse problem. Water Resour Res 22(2):95–108CrossRef

Yeh TCJ, Jin M, Hanna S (1996) An iterative stochastic inverse method: conditional effective transmissivity and hydraulic head fields. Water Resour Res 32(1):85–92CrossRef

Zanini A, Kitanidis PK (2009) Geostatistical inversing for large-contrast transmissivity fields. Stoch Env Res Risk A 23:565–577CrossRef

Zhang Y, Person M, Paola C, Gable CW, Wen X-H, Davis JM (2005) Geostatistical analysis of an experimental stratigraphy. Water Resour Res 41, W11416. doi:10.1029/2004WR003756

Zhang Y (2014) Nonlinear inversion of an unconfined aquifer: simultaneous estimation of heterogeneous hydraulic conductivities, recharge rates, and boundary conditions. Transp Porous Media 102:275–299. doi:10.1007/s11242-014-0275-x CrossRef

Zhang Y, Irsa J, Jiao JY (2014) Three-dimensional aquifer inversion under unknown boundary conditions. J Hydrol 509:416–429. doi:10.1016/j.jhydrol.2013.11.024 CrossRef

Zhou H, Gomez-Hernandez JJ, Li L (2014) Inverse methods in hydrogeology: evolution and recent trends. Adv Water Resour 63:22–37CrossRef

Zhu J, Yeh TCJ (2006) Analysis of hydraulic tomography using temporal moments of drawdown recovery data. Water Resour Res 42, W02403. doi:10.1029/2005WR004309 CrossRef

Zimmerman DA et al (1998) A comparison of seven geostatistically based inverse approaches to estimate transmissivities for modeling advective transport by groundwater flow. Water Resour Res 34(6):1373–1413CrossRef

Titel: Functional parameterization for hydraulic conductivity inversion with uncertainty quantification
verfasst von: Jianying Jiao
Ye Zhang
Publikationsdatum: 01.05.2015
Verlag: Springer Berlin Heidelberg
Erschienen in: Hydrogeology Journal / Ausgabe 3/2015
Print ISSN: 1431-2174
Elektronische ISSN: 1435-0157
DOI: https://doi.org/10.1007/s10040-014-1202-5

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