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Water Resources Management

Erschienen in:

01.12.2013

Predicting Shallow Water Table Depth at Regional Scale: Optimizing Monitoring Network in Space and Time

verfasst von: Emanuele Barca, Maria Costanza Calzolari, Giuseppe Passarella, Fabrizio Ungaro

Erschienen in: Water Resources Management | Ausgabe 15/2013

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Abstract

Shallow water table levels can be predicted using several approaches, either based on climatic records, on field evidences based on soil morphology, or on the outputs of physically based models. In this study, data from a monitoring network in a relevant agricultural area of Northern Italy (ca. 12,000 Km²) were used to develop a data driven model for predicting water table depth in space and time from meteorological data and long-term water table characteristics and to optimize sampling density in space and time. Evolutionary Polynomial Regressions (EPR) were used to calibrate a predictive tool based on climatic data and on the records from 48 selected sites (N = 5,611). The model was validated against the water table depths observed in 15 independent sites (N = 1,739), resulting in a mean absolute error of 30.8 cm (R ² = 0.61). The model was applied to the whole study area, using the geostatistical estimates of the average water table depth as input, to provide spatio-temporal maps of the water table depth. The impact of the degradation of data input in the temporal and spatial domain was then assessed following two approaches. In the first case, three different EPR models were calibrated based on 25 %, 50 % and 75 % of the available data, and the error indexes compared. In the second case, an increasing number of monitoring sites were removed from the initial data set, and the associated increased kriging standard deviation was assessed. Reducing the average sampling frequency from 1.5 per month to 1 every 40 days did not impact significantly on the prediction capability of the proposed model. Reducing the sampling frequency to 1 every 4 months resulted in a loss of accuracy <3 %, while removing more than half locations from the network, resulted in a global loss of information <15 %.

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Ashraf M, Loftis JC, Hubbard KG (1997) Application of geostatistics to evaluate partial weather station networks. Agric For Meteorol 84:255–271CrossRef

Barca E, Passarella G (2008) Spatial evaluation of the risk of groundwater quality degradation. A comparison between disjunctive kriging and geostatistical simulation. Environ Monit Assess 137(1–3):261–273CrossRef

Barca E, Passarella G, Uricchio V (2008) Optimal extension of the rain gauge monitoring network of the apulian regional consortium for crop protection. Environ Monit Assess 145(1–3):375–386CrossRef

Barca E, Passarella G, Morea A (2011) A software for optimal information based downsizing/upsizing of existing monitoring networks. Proceedings of Spatial Data Methods for Environmental and Ecological Processes—2nd Edition. 2011. Ed. Barbara Cafarelli, ISBN 978-88-96025-12-3

Barreto H, Howland FM (2005) Installing and using the bootstrap excel add-in software for introductory econometrics. Available at the following URL: http://www3.wabash.edu/econometrics/EconometricsBook/Basic%20Tools/ExcelAddIns/bootstrap.htm . Last accessed: 08.08.2013

Bogardi I, Bardossy A, Duckstein L (1985) Multicriterion network design using geostatistics. Water Resour Res 21:199–208CrossRef

Calzolari C, Ungaro F (2012) Predicting shallow water table depth at regional scale from rainfall and soil data. J Hydrol 414–415:374–387CrossRef

Carrera J, Szidarovzsky F (1985) Numerical comparison of network design algorithms for regionalized variables. Appl Math Comput 16:189–202CrossRef

Chen Z, Grasby SE, Osadetz KG (2002) Predicting average annual groundwater levels from climatic variables: an empirical model. J Hydrol 260:102–117CrossRef

D’Agostino V, Passarella G, Vurro M (1997) Assessment of the optimal sampling arrangement based on cokriging estimation variance reduction approach. Proceedings of the Congress of the International Association of Hydraulic Research, IAHR, 246–252

Deutsch CV, Journel AG (1998) GSLib: Geostatistical Software Library and User’s Guide. Oxford University Press, New York, 369 p

Doglioni A, Giustolisi O, Savic DA, Webb BW (2008) An investigation on stream temperature analysis based on evolutionary computing. Hydrol Process 22(3):315–326CrossRef

Efron B, Tibshirani RJ (1993) An introduction to the bootstrap. Monographs on statistics and applied probability, vol 57. Chapman & Hall, LondonCrossRef

Giustolisi O, Savic DA (2003) Evolutionary Polynomial Regression (EPR): development and applications. Report 2003/01. School of Engineering, Computer Science and Mathematics, Centre for Water Systems, University of Exeter

Giustolisi O, Savic DA (2006) A symbolic data-driven technique based on evolutionary polynomial regression. J Hydroinf 3(8):207–222

Giustolisi O, Savic DA (2009) Advances in data-driven analyses and modelling using EPR-MOGA. J Hydroinf 11(3–4):225–236CrossRef

Giustolisi O, Doglioni A, Savic DA, Webb BW (2007) A multi-model approach to analysis of environmental phenomena. Environ Model Softw 22:674–682CrossRef

Goldberg DE (1989) Genetic algorithm in search, optimization and machine learning. Addison-Wesley Longman Publishing Co., Inc, Boston

Harmancioglu NB, Alpaslan MN, Singh VP, Fistikoglu O, Ozkul SD (1999) Water quality monitoring network design. Kluwer Academic Publishers, BostonCrossRef

Isaaks EH, Srivastava RM (1989) An introduction to applied geostatistics. Oxford Unversity Press, New York

Janssen PHM, Heuberger PSC (1995) Calibration of process-oriented models. Ecol Model 83:55–66CrossRef

Journel AG, Huijbrechts CJ (1978) Mining geostatistics. Academic, London

Kim GB, Lee KK, Lee JY, Yi MJ (2007) Case study for determination of a water level monitoring frequency for nationwide groundwater monitoring networks in Korea. J Hydrol 342:223–237CrossRef

Kirkpatrick S, Gelatt CD Jr, Vecchi MP (1983) Optimization by simulated annealing. Science 220(4598):671–680CrossRef

Knopman DS, Voss CI (1989) Multiobjective sampling design for parameter estimation and model discrimination in groundwater solute transport. Water Resour Res 25:2245–2258CrossRef

Knotters M, Bierkens MFP (2001) Predicting water table depths in space and time using a regionalised time series model. Geoderma 103:51–77CrossRef

Laucelli D, Berardi L, Doglioni A (2010) EPR- Toolbox v. 2.1.SA. Technical University of Bari, Dpt. Of Civil and Environmental Engineering

Legates DR, McCabe GJ Jr (1999) Evaluating the use of “goodness-of-fit” measures in hydrologic and hydro climatic model validation. Water Resour Res 35(1):233–241CrossRef

Markus M, Hejazi MI, Bajcsy P, Giustolisi O, Savic DA (2010) Prediction of weekly nitrate-N fluctuations in a small agricultural watershed in Illinois. J Hydroinf 12(3):251–261CrossRef

Metropolis N, Rosenbluth A, Rosenbluth M, Teller A, Teller E (1953) Equation of state calculations by fast computing machines. J Chem Phys 21:1087–1092CrossRef

Meyer D, Valocchi AJ, Eheart JW (1994) Monitoring network design to provide initial detection of groundwater contamination. Water Resour Res 30:2647–2659CrossRef

Morgan CP, Stolt MH (2004) A comparison of several approaches to monitor water-table fluctuation. Soil Sci Soc Am J 68:562–566CrossRef

Owlia RR, Abrishamchi A, Tajrishy M (2011) Spatial–temporal assessment and redesign of groundwater quality monitoring network: a case study. Environ Monit Assess 172:263–273CrossRef

Pannatier Y (1996) Variowin: software for spatial analysis in 2D. Springer, New YorkCrossRef

Passarella G, Vurro M, D’Agostino V, Barcelona MJ (2003) Cokriging optimization of monitoring network configuration based on fuzzy and non-fuzzy variogram evaluation. Environ Monit Assess 82(1):1–21CrossRef

Rouhani S (1985) Variance reduction analysis. Water Resour Res 21(6):837–846CrossRef

Statios (2000) WinGslib version 1.3, Statios Software and Services, San Francisco, CA

Van Groenigen JW (2000) The influence of variogram parameters on optimal sampling schemes for mapping by kriging. Geoderma 97:223–236CrossRef

Van Groenigen JW, Stein A (1998) Spatial simulated annealing for constrained optimisation of spatial sampling schemes. J Environ Qual 27:1078–1086CrossRef

Van Groenigen JW, Siderius W, Stein A (1999) Constrained optimisation of soil sampling for minimisation of the kriging variance. Geoderma 87:239–259CrossRef

Van Groenigen JW, Pieters G, Stein A (2000) Optimizing spatial sampling for multivariate contamination in urban areas. Environmetrics 11:227–244CrossRef

Webster R, Heuvelink GBM (2006) The Kalman filter for the pedologist’s tool kit. Eur J Soil Sci 57:758–773CrossRef

Wu Y (2004) Optimal design of a groundwater monitoring network in Daqing, China. Environ Geol 45:527–535CrossRef

Zhou Y (1996) Sampling frequency for monitoring the actual state of groundwater systems. J Hydrol 180:301–318CrossRef

Titel: Predicting Shallow Water Table Depth at Regional Scale: Optimizing Monitoring Network in Space and Time
verfasst von: Emanuele Barca
Maria Costanza Calzolari
Giuseppe Passarella
Fabrizio Ungaro
Publikationsdatum: 01.12.2013
Verlag: Springer Netherlands
Erschienen in: Water Resources Management / Ausgabe 15/2013
Print ISSN: 0920-4741
Elektronische ISSN: 1573-1650
DOI: https://doi.org/10.1007/s11269-013-0461-6

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