Rainfall modeling using two different neural networks improved by metaheuristic algorithms
Rainfall is crucial for the development and management of water resources. Six hybrid soft computing models, including�multilayer perceptron (MLP)�Henry gas solubility optimization (HGSO), MLP�bat algorithm (MLP�BA), MLP�particle swarm optimization (MLP�PSO), radial basis neural network function (RB...
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my.uniten.dspace-338862024-10-14T11:17:23Z Rainfall modeling using two different neural networks improved by metaheuristic algorithms Sammen S.S. Kisi O. Ehteram M. El-Shafie A. Al-Ansari N. Ghorbani M.A. Bhat S.A. Ahmed A.N. Shahid S. 57192093108 6507051085 57113510800 16068189400 59157643200 58715013100 56432130100 57214837520 57195934440 Markov chain MLP Probability matrix Rainfall modelling RBFNN Malaysia Forecasting Markov processes Multilayer neural networks Particle swarm optimization (PSO) Soft computing Water management Gas solubility Mean absolute error Multilayers perceptrons Network functions Optimisations Probability matrixes Radial base neural network function Radial basis neural networks Rainfall modelling Testing process climate modeling climate prediction Markov chain optimization rainfall Rain Rainfall is crucial for the development and management of water resources. Six hybrid soft computing models, including�multilayer perceptron (MLP)�Henry gas solubility optimization (HGSO), MLP�bat algorithm (MLP�BA), MLP�particle swarm optimization (MLP�PSO), radial basis neural network function (RBFNN)�HGSO, RBFNN�PSO, and RBFGNN�BA, were used in this study to forecast monthly rainfall at two stations in Malaysia (Sara and Banding). Different statistical measures (mean absolute error (MAE) and Nash�Sutcliffe efficiency (NSE) and percentage of BIAS (PBIAS)) and a Taylor diagram were used to assess the models� performance. The results indicated that the MLP�HGSO performed better than the other models in forecasting rainfall at both stations. In addition, transition matrices were computed for each station and year based on the conditional probability of rainfall or absence of rainfall on a given month. The values of MAE for testing processes for the MLP�HGSO, MLP�PSO, MLP�BA, RBFNN�HGSO, RBFNN�BA, and RBFNN�PSO at the first station were 0.712, 0.755, 0.765, 0.717, 0.865, and 0.891, while the corresponding NSE and PBIAS values�were 0.90�0.23, 0.83�0.29, 0.85�0.25, 0.87�0.27, 0.81�0.31, and 0.80�0.35, respectively. For the second station, the values of MAE were found 0.711, 0.743, 0.742, 0.719, 0.863 and 0.890 for the MLP�HGSO, MLP�PSO, MLP�BA, RBFNN�HGSO, RBFNN�BA, and RBFNN�PSO during testing processes and the corresponding NSE�PBIAS values were 0.92�0.22, 0.85�0.28, 0.89�0.26, 0.91�0.25, 0.83�0.31, 0.82�0.32, respectively. Based on the outputs of the MLP�HGSO, the highest rainfall was recorded in 2012 with a probability of 0.72, while the lowest rainfall was recorded in 2006 with a probability of 0.52 at the Sara Station. In addition, the results indicated that the MLP�HGSO performed better than the other models within the Banding Station. According to the findings, the hybrid MLP�HGSO was selected as an effective rainfall prediction model. � 2023, The Author(s). Final 2024-10-14T03:17:23Z 2024-10-14T03:17:23Z 2023 Article 10.1186/s12302-023-00818-0 2-s2.0-85179670913 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85179670913&doi=10.1186%2fs12302-023-00818-0&partnerID=40&md5=761f23db03047f0a90d122bdf0ccb6ff https://irepository.uniten.edu.my/handle/123456789/33886 35 1 112 All Open Access Gold Open Access Springer Scopus |
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Markov chain MLP Probability matrix Rainfall modelling RBFNN Malaysia Forecasting Markov processes Multilayer neural networks Particle swarm optimization (PSO) Soft computing Water management Gas solubility Mean absolute error Multilayers perceptrons Network functions Optimisations Probability matrixes Radial base neural network function Radial basis neural networks Rainfall modelling Testing process climate modeling climate prediction Markov chain optimization rainfall Rain |
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Markov chain MLP Probability matrix Rainfall modelling RBFNN Malaysia Forecasting Markov processes Multilayer neural networks Particle swarm optimization (PSO) Soft computing Water management Gas solubility Mean absolute error Multilayers perceptrons Network functions Optimisations Probability matrixes Radial base neural network function Radial basis neural networks Rainfall modelling Testing process climate modeling climate prediction Markov chain optimization rainfall Rain Sammen S.S. Kisi O. Ehteram M. El-Shafie A. Al-Ansari N. Ghorbani M.A. Bhat S.A. Ahmed A.N. Shahid S. Rainfall modeling using two different neural networks improved by metaheuristic algorithms |
| description |
Rainfall is crucial for the development and management of water resources. Six hybrid soft computing models, including�multilayer perceptron (MLP)�Henry gas solubility optimization (HGSO), MLP�bat algorithm (MLP�BA), MLP�particle swarm optimization (MLP�PSO), radial basis neural network function (RBFNN)�HGSO, RBFNN�PSO, and RBFGNN�BA, were used in this study to forecast monthly rainfall at two stations in Malaysia (Sara and Banding). Different statistical measures (mean absolute error (MAE) and Nash�Sutcliffe efficiency (NSE) and percentage of BIAS (PBIAS)) and a Taylor diagram were used to assess the models� performance. The results indicated that the MLP�HGSO performed better than the other models in forecasting rainfall at both stations. In addition, transition matrices were computed for each station and year based on the conditional probability of rainfall or absence of rainfall on a given month. The values of MAE for testing processes for the MLP�HGSO, MLP�PSO, MLP�BA, RBFNN�HGSO, RBFNN�BA, and RBFNN�PSO at the first station were 0.712, 0.755, 0.765, 0.717, 0.865, and 0.891, while the corresponding NSE and PBIAS values�were 0.90�0.23, 0.83�0.29, 0.85�0.25, 0.87�0.27, 0.81�0.31, and 0.80�0.35, respectively. For the second station, the values of MAE were found 0.711, 0.743, 0.742, 0.719, 0.863 and 0.890 for the MLP�HGSO, MLP�PSO, MLP�BA, RBFNN�HGSO, RBFNN�BA, and RBFNN�PSO during testing processes and the corresponding NSE�PBIAS values were 0.92�0.22, 0.85�0.28, 0.89�0.26, 0.91�0.25, 0.83�0.31, 0.82�0.32, respectively. Based on the outputs of the MLP�HGSO, the highest rainfall was recorded in 2012 with a probability of 0.72, while the lowest rainfall was recorded in 2006 with a probability of 0.52 at the Sara Station. In addition, the results indicated that the MLP�HGSO performed better than the other models within the Banding Station. According to the findings, the hybrid MLP�HGSO was selected as an effective rainfall prediction model. � 2023, The Author(s). |
| author2 |
57192093108 |
| author_facet |
57192093108 Sammen S.S. Kisi O. Ehteram M. El-Shafie A. Al-Ansari N. Ghorbani M.A. Bhat S.A. Ahmed A.N. Shahid S. |
| format |
Article |
| author |
Sammen S.S. Kisi O. Ehteram M. El-Shafie A. Al-Ansari N. Ghorbani M.A. Bhat S.A. Ahmed A.N. Shahid S. |
| author_sort |
Sammen S.S. |
| title |
Rainfall modeling using two different neural networks improved by metaheuristic algorithms |
| title_short |
Rainfall modeling using two different neural networks improved by metaheuristic algorithms |
| title_full |
Rainfall modeling using two different neural networks improved by metaheuristic algorithms |
| title_fullStr |
Rainfall modeling using two different neural networks improved by metaheuristic algorithms |
| title_full_unstemmed |
Rainfall modeling using two different neural networks improved by metaheuristic algorithms |
| title_sort |
rainfall modeling using two different neural networks improved by metaheuristic algorithms |
| publisher |
Springer |
| publishDate |
2024 |
| _version_ |
1814061092929798144 |
| score |
13.214268 |