Abstract
Reliable and accurate streamflow forecasting plays a vital role in the optimal management of water resources. To improve the stability and accuracy of streamflow forecasting, a hybrid decomposition-ensemble model named VMD-LSTM-GBRT, which is sensitive to sampling, noise and long historical changes of streamflow, was established. The variational mode decomposition (VMD) algorithm was first applied to extract features, which were then learned by several long short-term memory (LSTM) networks. Simultaneously, an ensemble tree, a gradient boosting tree for regression (GBRT), was trained to model the relationships between the extracted features and the original streamflow. The outputs of these LSTMs were finally reconstructed by the GBRT model to obtain the forecasting streamflow results. A historical daily streamflow series (from 1/1/1997 to 31/12/2014) for Yangxian station, Han River, China, was investigated by the proposed model. VMD-LSTM-GBRT was compared with respect to three aspects: (1) feature extraction algorithm; ensemble empirical mode decomposition (EEMD) was used. (2) Feature learning techniques; deep neural networks (DNNs) and support vector machines for regression (SVRs) were exploited. (3) Ensemble strategy; the summation strategy was used. The results indicate that the VMD-LSTM-GBRT model overwhelms all other peer models in terms of the root mean square error (RMSE = 36.3692), determination coefficient (R2 = 0.9890), mean absolute error (MAE = 9.5246) and peak percentage threshold statistics (PPTS(5) = 0.0391%). The addressed approach based on the memory of long historical changes with deep feature representations had good stability and high prediction precision.
Highlights
Reliable and accurate streamflow forecasting plays a vital role in the optimal management of water resources
The results indicate that the variational mode decomposition (VMD)-long short-term memory (LSTM)-Gradient Boosting Regression Trees (GBRTs) model overwhelms all other peer models in terms of the root mean square error (RMSE = 36.3692), determination coefficient (R2 = 0.9890), mean absolute error (MAE = 9.5246) and peak percentage threshold statistics (PPTS(5) = 0.0391%)
To improve the accuracy and stability of forecasting, three aspects were considered in a comprehensive way: (1) multiscale feature extraction by the algorithm with much more robustness with respect to sampling and noise; nine feature terms were extracted by VMD in this paper
Summary
Reliable and accurate streamflow forecasting plays a vital role in the optimal management of water resources. An ensemble tree, a gradient boosting tree for regression (GBRT), was trained to model the relationships between the extracted features and the original streamflow The outputs of these LSTMs were reconstructed by the GBRT model to obtain the forecasting streamflow results. Due to the complicated non-linearity, extreme irregularity and multiscale variability of natural streamflow, the models directly built on original streamflow cannot appropriately identify streamflow change patterns[1] For this reason, the processes of transformation, data pre-processing and feature extraction have attracted the attention of many researchers. Feature representation of original data can contribute to the performance improvement of streamflow forecasting because of the advantage of feature extraction, which removes noise components and detect the hidden structures inside the raw time-series
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