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12 Goloka Behari Sahoo and Chittaranjan Ray Table 4. Continued Scenarios: Parameter excluded from the Predictive performance efficiency input subsets R RMSE ME Flush window 0.9896 0.1398 -0.0071 Well-site topography 0.9897 0.1339 0.0008 On site pesticide storage 0.9892 0.1353 0.0058 Well site topography 0.9897 0.1339 0.0008 5. Conclusion Prediction of pesticide occurrence in rural domestic wells is important. However, it is difficult to get information on soil characteristics and underlying physics of the pesticide movement in subsoil on a regional scale. Therefore, empirical models such as artificial neural networks are commonly employed as an alternative to predict the pesticide occurrence in a well using the available cause-effect information. Also, it is often difficult to get a large dataset for ANN. Since sampling and re-sampling is time-consuming and expensive, classifying the causeeffect information of the wells collected on a regional scale into some clusters and taking one/two well from each cluster as representative of that cluster is important. In this study, self-organizing map is used to cluster the wells into groups of similar characteristics. Two ANN models: (a) BPNN and (b) RBFN were optimized using μGA and were used to predict pesticide occurrence in a well. Results showed that selection of a suitable number for SOM neurons is important because a small SOM groups samples of wider characteristics into a cluster while a large SOM is unable to generate clusters each with enough samples to contribute equally to the three subsets. The SOM size found appropriate was a 8 × 8 grid that produced clusters each having more than 4 samples per clusters in this study. Given a suitable size of SOM, μGA-ANN models using two samples per cluster in the training subsets outperform to all other cases. Sensitivity analysis was carried out to measure the importance of that input parameter over other. This is done by deleting the input parameter from the subset. Results showed that depth of well, depth to aquifer material from land surface, and on-site pesticide storage facilities are important. These findings are consistent with previous studies. The results presented herein are based on the available dataset and on one site. However, the methodology can be applied to any other site with necessary modification. Acknowledgments Partial funding for this research was provided by the United States Department of Agriculture, National Research Initiative/Competitive Grants Program (Contract Number 99- 35102-8551, Project Number HAWR 1999-01133).
Use of Artificial Neural Networks for Predicting of <strong>Groundwater</strong> Contamination 13 References Aguilera, P.A., A.G. Frenich, J.A. Torres, H. Castro, J.L. M. Vidal, and M. Canton, (2001). Application of the Kohonen neural network in coastal water management: methodological development for the assessment and prediction of water quality. Water Research, 35 (17), 4053-4062. Alp, M. and H.K. Cigizoglu (2007). Suspended sediment load simulation by two artificial neural network methods using hydrometeorological data, Environ. Modell. Softw., 22(1), 2–13. ASCE Task Committee (2000). Artificial neural network in hydrology, J. Hydrol. Eng., 5(2), 124–144. Barbash, J.E. and E.A. Resek (1996). Pesticides in ground water: distribution, trends, and governing factors, 590 pp., Lewis Publishers, Boca Raton, FL. Barbash, J.E., G.P. Thelin, D.W. Kolpin, and R.J. Gillom (1999). Distribution of major herbicides in ground water of the United States, Water Resources Investigations Report 98–4245, 64 pp., U.S. Geological Survey. Birikundavyi, S., R. Labib, H.T. Trung, and J. Rousselle (2002). Performance of neural networks in daily streamflow forecasting, J. Hydrol. Eng., 7(5), 392–398. Bowden, G.J., H.R. Maier and G.C. Dandy (2002). Optimal division of data for neural networks models in water resources applications, Water Resour. Res., 38(2), doi: 10.1029/2001WR000266. Brodnjak-Vončina, D., D. Dobčnik, M. Novič, and J. Zupan (2002). Chemometrics Characterisation of the quality of river water, Anal. Chim. Acta, 462(1), 87–100. Carroll, D.L. (1999). FORTRAN Genetic Algorithm (GA) Driver version 1.7.0, Available from http://www.cuaerospace.com/carroll/ga.html (accessed during January 2006) Carsel, R.F, C.N. Smith, L.A. Mulkey, J.D. Dean, and P. Jowsie (1984). Pesticide root zone model (PRZM), Release 1, EPA–600/3–84–109, USEPA, Washington, D.C. Karul, C., S. Soyupak, A.F. Cilesiz, N. Akbay, and E. Germen, (2000). Case studies on the use of neural networks in eutrophication modeling. Ecological Modelling, 134, 145-152. Knisel, W.G. (1993). GLEAMS: groundwater loading effects of agricultural management systems, version 2.10, University of Georgia Coastal Plain Experimental Station, Tifton, GA. Kohonen, T. (1982). Self-organized formation of topologically correct feature maps, Biol. Cybern., 43, 59–69. Kolpin, D.W., E.M. Thurman and D.A. Goolsby (1996). Occurrence of selected pesticides and their metabolites in near surface aquifers of the Midwestern United States, Environ. Sci. Technol., 30, 335–350. Kolpin, D.W., M.R. Burkart and E.M. Thurman (1994). Herbicides and nitrate in near-surface aquifers in the mid-continental United States, 1991, Water Supply Paper 2413, U.S. Geological Survey. Lischeid, G. (2001). Investigating trends of hydrochemical time series of small catchments by artificial neural netwroks, Physics and Chemistry of the Earth, 26 (1), 15-18. Maier, H.R. and G.C. Dandy (2000). Neural networks for the prediction and forecasting of water resources variables: a review of <strong>modelling</strong> issues and applications, Environ. Modell. Softw., 15(1), 101–124.
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Water Budget Preliminary Studies fo
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Groundwater Management in the North
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308 K.L. Katsifarakis McKinney, D.C
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310 Nigel J. Cassidy 1.0. Introduct
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312 Nigel J. Cassidy separation). U
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314 Nigel J. Cassidy needed to char
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316 Nigel J. Cassidy resolution min
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318 Nigel J. Cassidy al., 2005; Eve
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