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  • 1
    Language: English
    In: Computers and Geosciences, July, 2012, Vol.44, p.78(8)
    Description: To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.cageo.2012.03.014 Byline: Ronnie L. Schwede (a), Adrian Ngo (b), Peter Bastian (b), Olaf Ippisch (b), Wei Li (a), Olaf A. Cirpka (a) Abstract: Hydraulic conductivity is a key parameter for the simulation of groundwater flow and transport. Typically, it is highly variable in space and difficult to determine by direct methods. The most common approach is to infer hydraulic-conductivity values from measurements of dependent quantities, such as hydraulic head and concentration. In geostatistical inversion, the parameters are estimated as continuous, spatially auto-correlated fields, the most likely values of which are obtained by conditioning on the indirect data. In order to identify small-scaled features, a fine three-dimensional discretization of the domain is needed. This leads to high computational demands in the solution of the forward problem and the calculation of sensitivities. In realistic three-dimensional settings with many measurements parallel computing becomes mandatory. In the present study, we investigate how parallelization of the quasi-linear geostatistical approach of inversion can be made most efficient. We suggest a two-level approach of parallelization, in which the computational domain is subdivided and the evaluation of sensitivities is also parallelized. We analyze how these two levels of parallelization should be balanced to optimally exploit a given number of computing nodes. Author Affiliation: (a) University of Tubingen, Center for Applied Geoscience, Holderlinstr. 12, 72074 Tubingen, Germany (b) University of Heidelberg, Interdisciplinary Center of Scientific Computing, Im Neuenheimer Feld 368, 69120 Heidelberg, Germany Article History: Received 20 December 2011; Revised 24 February 2012; Accepted 19 March 2012
    Keywords: Hydrogeology -- Analysis ; Groundwater Flow -- Analysis ; Hydraulic Flow -- Analysis ; Groundwater -- Analysis ; Geostatistics -- Analysis
    ISSN: 0098-3004
    Source: Cengage Learning, Inc.
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