Publications

Sedighi, F; Vafakhah, M; Javadi, MR (2016). Rainfall-Runoff Modeling Using Support Vector Machine in Snow-Affected Watershed. ARABIAN JOURNAL FOR SCIENCE AND ENGINEERING, 41(10), 4065-4076.

Abstract
Flood is one of the devastating natural disasters prediction of which is significantly important. Rainfall-runoff process and flooding are physical phenomena that their investigation is very difficult due to effectiveness of different parameters. Various methods have been implemented to analyze these phenomena. The aim of current study is to investigate the performance of the artificial neural network (ANN) (hyperbolic tangent and sigmoid) and support vector machine (SVM) (regression type-1 and regression type-2) models to simulate the rainfall-runoff process influenced by snow water equivalent (SWE) height in Roodak watershed, Tehran province, Iran. So, 92 MODIS images were gained from NASA website for three water years of 2003-2005. Then, snow cover areas in all images were extracted and finally SWE values were calculated. Also, the data of precipitation, temperature and discharge for the mentioned years were used for modeling. According to the results, ANN with the hyperbolic tangent function, rainfall-temperature SWE inputs, 1-day delay and RMSE and R-2 of 0.024 and 0.77, and the model with the sigmoid transfer function, rain-temperature-SWE inputs and RMSE and R-2 of 0.026 and 0.75 had better prediction capability than the other models. This indicates that the SWE has improved the accuracy of the models. The results of the SVM model indicate that the model with the rainfall-temperature-SWE, 1-delay, type-1 regression, RBF function and RMSE and R-2 of 0.054 and 0.030 had better prediction capability than other models. This also shows that consideration of the SWE enhances the performance and accuracy of the SVM models. Moreover, comparing the results of ANN and SVM models, it can be concluded that ANN model with the rainfall-temperature SWE inputs, 1-day delay, and the hyperbolic tangent function had better predictions.

DOI:
10.1007/s13369-016-2095-5

ISSN:
2193-567X