Abstract
Hydrological modeling is one of the important subjects in managing water resources and the processes of predicting stochastic behavior. Developing Data-Driven Models (DDMs) to apply to hydrological modeling is a very complex issue because of the stochastic nature of the observed data, like seasonality, periodicities, anomalies, and lack of data. As streamflow is one of the most important components in the hydrological cycle, modeling and estimating streamflow is a crucial aspect. In this study, two models, namely, Optimally Pruned Extreme Learning Machine (OPELM) and Chi-Square Automatic Interaction Detector (CHAID) methods were used to model the deterministic parts of monthly streamflow equations, while Autoregressive Conditional Heteroskedasticity (ARCH) was used in modeling the stochastic parts of monthly streamflow equations. The state of art and innovation of this study is the integration of these models in order to create new hybrid models, ARCH-OPELM and ARCH-CHAID, and increasing the accuracy of models. The study draws on the monthly streamflow data of two different river stations, located in north-western Iran, including Dizaj and Tapik, which are on Nazluchai and Baranduzchai, gathered over 31 years from 1986 to 2016. To ascertain the conclusive accuracy, five evaluation metrics including Correlation Coefficient (R), Root Mean Square Error (RMSE), Nash–Sutcliffe Efficiency (NSE), Mean Absolute Error (MAE), the ratio of RMSE to the Standard Deviation (RSD), scatter plots, time-series plots, and Taylor diagrams were used. Standalone CHAID models have better results than OPELM methods considering sole models. In the case of hybrid models, ARCH-CHAID models in the validation stage performed better than ARCH-OPELM for Dizaj station (R = 0.96, RMSE = 1.289 m3/s, NSE = 0.92, MAE = 0.719 m3/s and RSD = 0.301) and for Tapik station (R = 0.94, RMSE = 2.662 m3/s, NSE = 0.86, MAE = 1.467 m3/s and RSD = 0.419). The results remarkably reveal that ARCH-CHAID models in both stations outperformed all other models. Finally, it is worth mentioning that the new hybrid “ARCH-DDM” models outperformed standalone models in predicting monthly streamflow.
Highlights
It is widely acknowledged that the number and diversity of water-related challenges are large and are expected to increase in the future
The stochastic term of streamflow models was calculated by autoregressive conditional heteroskedasticity heteroskedasticity (ARCH) model that described the variance of the current error term or innovation as a function of the actual sizes of the previous time periods’ error terms, and afterward, the results of hybrid (ARCH-OPELM and ARCH-Chi-square automatic automatic interaction interaction detector detector (CHAID)) models were reported
The correlograms of monthly streamflow, as an input variable determined by autocorrelation, and partial autocorrelation functions for both stations of Dizaj and Tapik were illustrated for 20 months
Summary
It is widely acknowledged that the number and diversity of water-related challenges are large and are expected to increase in the future. Predicting streamflow has been conducted by researches on different scales such as hourly scales [4], daily scales [5], 10 days scales [6,7,8], monthly scales [9], and annual scales [10]. It is a difficult and challenging task for modelers to predict streamflow due to its complex (nonlinear) and non-deterministic characteristics. The execution of all simulation and predicting models is strongly based on the quality of the input data [11]
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