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Water Resources Management

Erschienen in:

03.04.2019

Artificial Neural Network and Support Vector Machine Models for Inflow Prediction of Dam Reservoir (Case Study: Zayandehroud Dam Reservoir)

verfasst von: Mohammad Babaei, Ramtin Moeini, Eghbal Ehsanzadeh

Erschienen in: Water Resources Management | Ausgabe 6/2019

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Abstract

Inflow prediction of reservoirs is of considerable importance due to its application in water resources management related to downstream water release planning and flood protection. Therefore, in this research, different new input patterns for predicting inflow to Zayandehroud dam reservoir is proposed employing artificial neural network (ANN) and support vector machine (SVM) models. Nine different models with different patterns of input data such as inflow to the dam reservoir considering time duration lags, time index, and monthly rainfall of Ghaleh-Shahrokh station have been proposed to predict the inflow to the dam reservoir. Comparison of the results indicates that the ninth proposed model has the least error for inflow prediction in which the results of SVM model outperform those of ANN model. That is, the least error has been obtained using the ninth SVM (ANN) model with correlation coefficient (R) values of 0.8962 (0.89296), 0.9303 (0.92983) and 0.9622 (0.95333) and root mean squared error (RMSE) values of 47.9346 (48.5441), 42.69093 (43.748) and 23.56193 (28.5125) for training, validation and test data, respectively.

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Asefa T, Kemblowski MW, Urroz G, McKee M, Khalil A (2004) Support vectors-based groundwater head observation networks design. Water Resour Res 40(11):W11509CrossRef

Asefa T, Kemblowski MW, McKee M, Khalil A (2006) Multi-time scale stream flow predictions: the support vector machines approach. J Hydrol 318:7–16CrossRef

Awchi TA (2014) River discharges forecasting in northern Iraq using different ANN techniques. Water Resour Manag 28(3):801–814CrossRef

Coulibali CG (1999) Daily stream flow forecasting: application of ANN. J Hydrol 3:123–128

Coulibaly P, Anctil F, Bobee B (2000) Daily reservoir inflow forecasting using artificial neural networks with stopped training approach. J Hydrol 230(3):244–257CrossRef

Dibike YB, Yelickov S, Solomatine DP, Abbott MB (2001) Model induction with support vector machines: introduction and application. Journal of Computing in Civil Engineering Management 15(3):208–216CrossRef

Hassan M, Shamim MA, Hashmi HN, Ashiq SZ, Ahmed I, Pasha GA, Naeem UA, Ghumman AR, Han D (2015) Predicting streamflows to amultipurpose reservoir using artificial neural networks and regression techniques. Earth Sci Inf 8(2):337–352CrossRef

He Z, Wen X, Liu H, Du J (2014) A comparative study of artificial neural network, adaptive neuro fuzzy inference system and support vector machine for forecasting river flow in the semiarid mountain region. J Hydrol 509:379–386CrossRef

Jamali S, Abrishamchi A, Tajrishi M (2007) River stream-flow and Zayanderoud reservoir operation modeling using the fuzzy inference system. Journal of Water and Wastewater 18(4):25–34 (in Persian)

Kalteh AM (2015) Wavelet genetic algorithm-support vector regression (wavelet GA-SVR) for monthly flow forecasting. Water Resour Manag 29(4):1283–1293CrossRef

Kisi O (2008) River flow forecasting and estimation using different artificial neural network techniques. Hydrol Res 39(1):27–40CrossRef

Kisi O, Cimen M (2011) A wavelet–support vector machine conjunction model for monthly streamflow forecasting. J Hydrol 399:132–140CrossRef

Lima LM, Popova E, Damien P (2014) Modeling and forecasting of Brazilian reservoir inflows via dynamic linear models. Int J Forecast 30(3):464–476CrossRef

Lin J-Y, Cheng C-T, Chau K-W (2006) Using support vector machines for long-term discharge prediction. Hydrol Sci J 51(4):599–612CrossRef

Liong S, Sivapragasam C (2002) Flood stage forecasting with support vector machines. J Am Water Resour Assoc 38:173–186CrossRef

Liu Z, Zhou P, Zhang Y (2014) A probabilistic wavelet–support vector regression model for stream flow forecasting with rainfall and climate information input. J Hydrometeorol 16:2209–2229CrossRef

Liu J, Yan K, Zhao X, Hu Y (2016) Prediction of autogenous shrinkage of concretes by support vector machine. International Journal of Pavement Research and Technology 9(3):169–177CrossRef

Lohani AK, Kumar R, Singh RD (2012) Hydrological time series modeling: a comparison between adaptive neuro-fuzzy, neural network and autoregressive techniques. J Hydrol 442-443:23–35CrossRef

Menhaj MB (2009) Computational intelligence. AmirKabir University of Technology (in persian)

Noori R, Khakpour AR, Omidvar B, Farokhnia A (2010) Comparison of ANN and principal component analysis-multivariate linear regression models for predicting the river flow based on developed discrepancy ratio statistic. Expert Syst Appl 37(8):5856–5862CrossRef

Noori R, Karbassi AR, Moghaddamnia A, Han D, Zokaei-Ashtiani MH, Farokhnia A, Ghafari Gousheh M (2011a) Assessment of input variables determination on the SVM model performance using PCA, gamma test and forward selection techniques for monthly stream flow prediction. J Hydrol 401:177–189CrossRef

Noori R, Karbassi AR, Mehdizadeh HM, Vesali-Naseh M, Sabahi MS (2011b) A framework development for predicting the longitudinal dispersion coefficient in natural streams using an artificial neural network. Environ Prog Sustain Energy 30(3):439–449CrossRef

Sattari MT, Yurekli K, Pal M (2012) Performance evaluation of artificial neural network approaches in forecasting reservoir inflow. Appl Math Model 36(6):2649–2657CrossRef

Smola AJ, Scholkopf B (1998) A tutorial on support vector regression. NeuroCOLT2 Technical Report Series. NC2-TR-1998-030

Valipour M, Banihabib ME, Behbahani SMR (2013) Comparison of the ARMA, ARIMA, and the autoregressive artificial neural. J Hydrol 476:433–441CrossRef

Vapnik V (1995) The nature of statistical learning theory. Springer-Verlag, New YorkCrossRef

Vapnik V (1998) Statistical learning theory. Wiley, New York

Wenjian W, Changqian M, Weizhen L (2008) Online prediction model based on support vector machine. Neurocomputing 71(5):550–558

Yazdani MR, Saghafian B, Mahdian MH, Soltani S (2009) Monthly runoff estimation using artificial neural networks. J Agric Sci Technol 11(3):355–362

Yu PS, Chen ST, Chang IF (2006) Support vector regression for real-time flood stage forecasting. J Hydrol 328:704–716CrossRef

ZayandAb Consulting Engineers (2008) Studies on resources and water consumption for Zayandehroud Basin. Isfahan Regional Water Company

Zhu S, Zhou J, Ye L, Meng C (2016) Stream flow estimation by support vector machine coupled with different methods of time series decomposition in the upper reaches of Yangtze River, China. Environ Earth Sci 75(531):1–12

Titel: Artificial Neural Network and Support Vector Machine Models for Inflow Prediction of Dam Reservoir (Case Study: Zayandehroud Dam Reservoir)
verfasst von: Mohammad Babaei
Ramtin Moeini
Eghbal Ehsanzadeh
Publikationsdatum: 03.04.2019
Verlag: Springer Netherlands
Erschienen in: Water Resources Management / Ausgabe 6/2019
Print ISSN: 0920-4741
Elektronische ISSN: 1573-1650
DOI: https://doi.org/10.1007/s11269-019-02252-5

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