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Earth Science Informatics
Erschienen in: Earth Science Informatics 4/2014

01.12.2014 | Research Article

Successive-station monthly streamflow prediction using neuro-wavelet technique

verfasst von: Ali Danandeh Mehr, Ercan Kahya, Farzaneh Bagheri, Ekin Deliktas

Erschienen in: Earth Science Informatics | Ausgabe 4/2014

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Abstract

This study investigates the effect of discrete wavelet transform data pre-processing method on neural network-based successive-station monthly streamflow prediction models. For this aim, using data from two successive gauging stations on Çoruh River, Turkey, we initially developed eight different single-step-ahead neural monthly streamflow prediction models. Typical three-layer feed-forward (FFNN) topology, trained with Levenberg-Marquardt (LM) algorithm, has been employed to develop the best structure of each model. Then, the input time series of each model were decomposed into subseries at different resolution modes using Daubechies (db4) wavelet function. At the next step, eight hybrid neuro-wavelet (NW) models were generated using the subseries of each model. Ultimately, root mean square error and Nash-Sutcliffe efficiency measures have been used to compare the performance of both FFNN and NW models. The results indicated that the successive-station prediction strategy using a pair of upstream-downstream records tends to decrease the lagged prediction effect of single-station runoff-runoff models. Higher performances of NW models compared to those of FFNN in all combinations demonstrated that the db4 wavelet transform function is a powerful tool to capture the non-stationary feature of the successive-station streamflow process. The comparative performance analysis among different combinations showed that the highest improvement for FFNN occurs when simultaneous lag-time is considered for both stations.
Nächster Artikel Group Method of Data Handling to Predict Scour at Downstream of a Ski-Jump Bucket Spillway

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Literatur
Abrahart RJ, See L (2000) Comparing neural network (NN) and auto regressive moving average (ARMA) techniques for the provision of continuous river flow forecasts in two contrasting catchments. Hydrol Process 14:2157–2172CrossRef
Abrahart RJ, Anctil F, Coulibaly P, Dawson CW, Mount NJ, See LM, Shamseldin AY, Solomatine DP, Toth E, Wilby RL (2012) Two decades of anarchy? Emerging themes and outstanding challenges for neural network modelling of surface hydrology. Prog in Phys Geogr 36(4):480–513CrossRef
Adamowski J (2008) Development of a short-term river flood forecasting method for snowmelt driven floods based on wavelet and cross-wavelet analysis. J Hydrol 353:247–266CrossRef
Adamowski J, Sun K (2010) Development of a coupled wavelet transform and neural network method for flow forecasting of non-perennial rivers in semi-arid watersheds. J Hydrol 390:85–91CrossRef
Addison PS, Murrary KB, Watson JN (2001) Wavelet transform analysis of open channel wake flows. J Eng Mech 127(1):58–70CrossRef
Altunkaynak A (2007) Forecasting surface water level fluctuations of Lake Van by artificial neural networks. Water Resour Manage 21:399–408CrossRef
ASCE Task committee (2000) Artificial neural networks in hydrology: hydrologic applications. J Hydrol Eng 5(2):124–137CrossRef
Aytek A, Guven A, Yuce MI, Aksoy H (2008) An explicit neural network formulation for evapotranspiration. Hydrol Sci J 53(4):893–904CrossRef
Besaw LE, Rizzo DM, Bierman PR, Hackett WR (2010) Advances in ungauged streamflow prediction using artificial neural networks. J Hydrol 386:27–37CrossRef
Can İ, Tosunogulu F, Kahya E (2012) Daily streamflow modelling using autoregressive moving average and artificial neural networks models: case study of Çoruh basin, Turkey. Water and Environ J 26:567–576CrossRef
Cannas B, Fanni A, See L, Sias G (2006) Data preprocessing for river flow forecasting using neural networks: Wavelet transforms and data partitioning. Phys Chem Earth, PartsA/B/C 31(18):1164–1171CrossRef
Chang LC, Chang FJ, Chiang YM (2004) A two-step ahead recurrent neural network for streamflow forecasting. Hydrol Processes 18:81–92CrossRef
Chang FJ, Chiang YM, Chang LC (2007) Multi-step-ahead neural networks for flood forecasting. Hydrol Sci J 52(1):114–130CrossRef
Chau KW, Wu CL (2011) Hydrological predictions using data-driven models coupled with data pre-processing Lap Lambert academic publishing. Saarbrücken, Germany
Chau KW, Wu CL, Li YS (2005) Comparison of several flood forecasting models in Yangtze River. J Hydrol Eng 10(6):485–491CrossRef
Cheng CT, Chau KW, Sun YG, Lin JY (2005) Long-term prediction of discharges in Manwan Reservoir using artificial neural network models. Lect Notes Comput Sc 3498:1040–1045CrossRef
Coulibaly P, Burn HD (2004) Wavelet analysis of variability in annual Canadian streamflows. Water Resour Res 40, W03105CrossRef
Dahamshe A, Aksoy H (2009) Artificial neural network models for forecasting intermittent monthly precipitation in arid regions. Meteorol Appl 16:325–337CrossRef
Daubechies I (1990) The wavelet transform, time-frequency localization and signal analysis. IEEE Trans Inf Theory 36(5):961–1005CrossRef
De Vos NJ, Rientjes THM (2005) Constraints of artificial neural networks for rainfall–runoff modeling: trade-offs in hydrological state representation and model evaluation. Hydrol Earth Syst Sci 9:111–126CrossRef
Elshorbagy A, Corzo G, Srinivasulu S, Solomatine DP (2010) Experimental investigation of the predictive capabilities of data driven modeling techniques in hydrology - Part 1: Concepts and methodology. Hydrol Earth Syst Sci 14:1931–1941CrossRef
Guang-Te W, Singh VP (1994) An autocorrelation function method for estimation of parameters of autoregressive models. Water Resour Manage 8:33–56CrossRef
Haykin S (1999) Neural networks, a comprehensive foundation. Prentice Hall, Upper Saddle River, NJ
Hornik K, Stinchcombe M, White M (1989) Multi-layer feed forward networks are universal approximators. Neural Networks 2(5):359–366CrossRef
Kakahaji H, Dehghan Banadaki H, Kakahaji A, Kakahaji A (2013) A Prediction of Urmia Lake water-level fluctuations by using analytical, linear statistic and intelligent methods. Water Resour Manage 27:4469–4492CrossRef
Kisi O (2004) River flow modeling using artificial neural network. J Hydrol Eng 9(1):60–63CrossRef
Kisi O (2007) Streamflow forecasting using different artificial neural network algorithms. J Hydrol Eng 12(5):532–539CrossRef
Kisi O (2008) Stream flow forecasting using neuro-wavelet technique. Hydrol Process 22:4142–4152CrossRef
Kisi O (2009) Neural networks and wavelet conjunction model for intermittent streamflow forecasting. J Hydrol Eng 14(8):773–782CrossRef
Kisi O (2010) Wavelet regression model for short-term streamflow forecasting. J Hydrol 389:344–353CrossRef
Kücük M, Agiralioglu N (2006) Regression technique for stream flow prediction. J Appl Stat 33(9):943–960CrossRef
Lin JY, Cheng CT, Sun YG, Chau KW (2005) Long-term prediction of discharges in Manwan Hydropower using adaptive-network-based fuzzy inference systems models. Lect Notes Comput Sc 3612:1152–1161CrossRef
Makkeasorn A, Chang NB, Zhou X (2008) Short-term streamflow forecasting with global climate change implications – A comparative study between genetic programming and neural network models. J Hydrol 352:336–354CrossRef
Mallat S (1998) A Wavelet tour of signal processing, 2nd edn. Academic Press, San Diego, CA
Modarres R (2009) Multi-criteria validation of artificial neural network rainfall-runoff modeling. Hydrol Earth Syst Sci 13:411–421CrossRef
Mondal MS, Wasimi SA (2006) Generating and forecasting monthly flows of the Ganjes River with PAR Model. J Hydrol 232:41–56CrossRef
Muttil N, Chau KW (2006) Neural network and genetic programming for modelling coastal algal blooms. Int J Environ Pollut 28(3–4):223–238CrossRef
Niu J, Sivakumar B (2013) Scale-dependent synthetic streamflow generation using a continuous wavelet transform. J Hydro 496:71–78CrossRef
Nourani V, Mogaddam AA, Nadiri AO (2008) An ANN based model for spatiotemporal groundwater level forecasting. Hydrol Process 22:5054–5066CrossRef
Nourani V, Alami MT, Aminfar MH (2009) A combined neural-wavelet model for prediction of Ligvanchai watershed precipitation. Eng Appl Artif Intell 22(3):466–472CrossRef
Nourani V, Kisi Ö, Komasi M (2011) Two hybrid Artificial Intelligence approaches for modelling rainfall–runoff process. J Hydrol 402:41–59CrossRef
Nourani V, Komasi M, Alami MT (2012) Hybrid Wavelet–Genetic Programming Approach to Optimize ANN Modelling of Rainfall–Runoff Process. J Hydrol Eng 17(6):724–741CrossRef
Nourani V, Hosseini Baghanam A, Adamowski J, Gebremichael M (2013) Using self-organizing maps and wavelet transforms for space–time pre-processing of satellite precipitation and runoff data in neural network based rainfall–runoff modeling. J Hydrol 476:228–243CrossRef
Onderka M, Banzhaf S, Scheytt T, Krein A (2013) Seepage velocities derived from thermal records using wavelet analysis. J Hydrol 479:64–74CrossRef
Ozger M (2010) Significant wave height forecasting using wavelet fuzzy logic approach. Ocean Eng 37:1443–1451CrossRef
Partal T, Kisi O (2007) Wavelet and neuro-fuzzy conjunction model for precipitation forecasting. J Hydrol 342:199–212CrossRef
Partal T, Küçük M (2006) Long-term trend analysis using discrete wavelet components of annual precipitations measurements in Marmara region (Turkey). Phys Chem Earth 31:1189–1200CrossRef
Priddy KL, Keller PB (2005) Artificial neural networks, an introduction. SPIE Press, WashingtonCrossRef
Principe JC, Euliano NR, Curt Lefebvre W (2000) Neural and Adaptive Systems. Wiley & Sons.
Rajaee T, Nourani V, Mohammad ZK, Kisi O (2011) River suspended sediment load prediction: application of ANN and wavelet conjunction model. J Hydrol Eng 16(8):613–627CrossRef
Rathinasamy M, Khosa R (2012) Multi-scale nonlinear model for monthly streamflow forecasting: a wavelet-based approach. J Hydroinform 14(2):424–442CrossRef
Rezaeianzadeh M, Stein A, Tabari H, Abghari H, Jalalkamali N, Hosseinipour EZ, Singh VP (2013a) Assessment of a conceptual hydrological model and artificial neural networks for daily outflows forecasting. Int J Environ Sci Technol 10(6):1181–1192CrossRef
Rezaeianzadeh M, Tabari H, Abghari H (2013b) Prediction of monthly discharge volume by different artificial neural network algorithms in semi-arid regions. Arab J Geosci 6:2529–2537CrossRef
Sajikumar N, Thandaveswara BS (1999) A non-linear rainfall-runoff model using an artificial network. J Hydrol 216(4):32–55CrossRef
Shiri J, Kisi O (2010) Short-term and long-term streamflow forecasting using a wavelet and neuro-fuzzy conjunction model. J Hydrol 394:486–493CrossRef
Sudheer KP, Gosain AK, Ramasastri KS (2002) A data driven algorithm for constructing artificial neural network rainfallrunoff models. Hydrol Process 16(6):1325–1330CrossRef
Tahershamsi A, Majdzade Tabatabai MR, Shirkhani R (2012) An evaluation model of artificial neural network to predict stable width in gravel bed rivers. Int J Environ Sci Technol 9:333–342CrossRef
Taormina R, Chau KW, Sethi R (2012) Artificial neural network simulation of hourly groundwater levels in a coastal aquifer system of the Venice lagoon. Eng Appl Artif Intel 25(8):1670–1676CrossRef
Wang WC, Chau KW, Cheng CT, Qiu L (2009) A comparison of performance of several artificial intelligence methods for forecasting monthly discharge time series. J Hydrol 374:294–306CrossRef
Wu CL, Chau KW, Li YS (2009a) Methods to improve neural network performance in daily flows prediction. J Hydrol 372:80–93CrossRef
Wu CL, Chau KW, Li YS (2009b) Predicting monthly streamflow using data-driven models coupled with data-preprocessing techniques. Water Resour Res 45, W08432CrossRef
Zhou HC, Peng Y, Liang G (2008) The research of monthly discharge predictor–corrector model based on wavelet decomposition. Water Resour Manage 22(2):217–227CrossRef
Metadaten
Titel
Successive-station monthly streamflow prediction using neuro-wavelet technique
verfasst von
Ali Danandeh Mehr
Ercan Kahya
Farzaneh Bagheri
Ekin Deliktas
Publikationsdatum
01.12.2014
Verlag
Springer Berlin Heidelberg
Erschienen in
Earth Science Informatics / Ausgabe 4/2014
Print ISSN: 1865-0473
Elektronische ISSN: 1865-0481
DOI
https://doi.org/10.1007/s12145-013-0141-3

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