An advanced hybrid deep learning model for predicting total dissolved solids and electrical conductivity (EC) in coastal aquifers
For more than one billion people living in coastal regions, coastal aquifers provide a water resource. In coastal regions, monitoring water quality is an important issue for policymakers. Many studies mentioned that most of the conventional models were not accurate for predicting total dissolved sol...
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my.um.eprints.457262024-11-11T03:51:06Z http://eprints.um.edu.my/45726/ An advanced hybrid deep learning model for predicting total dissolved solids and electrical conductivity (EC) in coastal aquifers Jamshidzadeh, Zahra Latif, Sarmad Dashti Ehteram, Mohammad Khozani, Zohreh Sheikh Ahmed, Ali Najah Sherif, Mohsen El-Shafie, Ahmed TA Engineering (General). Civil engineering (General) For more than one billion people living in coastal regions, coastal aquifers provide a water resource. In coastal regions, monitoring water quality is an important issue for policymakers. Many studies mentioned that most of the conventional models were not accurate for predicting total dissolved solids (TDS) and electrical conductivity (EC) in coastal aquifers. Therefore, it is crucial to develop an accurate model for forecasting TDS and EC as two main parameters for water quality. Hence, in this study, a new hybrid deep learning model is presented based on Convolutional Neural Networks (CNNE), Long Short-Term Memory Neural Networks (LOST), and Gaussian Process Regression (GPRE) models. The objective of this study will contribute to the sustainable development goal (SDG) 6 of the united nation program which aims to guarantee universal access to clean water and proper sanitation. The new model can obtain point and interval predictions simultaneously. Additionally, features of data points can be extracted automatically. In the first step, the CNNE model automatically extracted features. Afterward, the outputs of CNNE were flattened. The LOST used flattened arrays for the point prediction. Finally, the outputs of the GPRE model receives the outputs of the LOST model to obtain the interval prediction. The model parameters were adjusted using the rat swarm optimization algorithm (ROSA). This study used PH, Ca + + , Mg2 + , Na + , K + , HCO3, SO4, and Cl- to predict EC and TDS in a coastal aquifer. For predicting EC, the CNNE-LOST-GPRE, LOST-GPRE, CNNE-GPRE, CNNE-LOST, LOST, and CNNE models achieved NSE values of 0.96, 0.95, 0.92, 0.91, 0.90, and 0.87, respectively. Sodium adsorption ratio, EC, magnesium hazard ratio, sodium percentage, and total hardness indices were used to evaluate the quality of GWL. These indices indicated poor groundwater quality in the aquifer. This study shows that the CNNE-LOST-GPRE is a reliable model for predicting complex phenomena. Therefore, the current developed hybrid model could be used by private and public water sectors for predicting TDS and EC for enhancing water quality in coastal aquifers. Springer 2024-01 Article PeerReviewed Jamshidzadeh, Zahra and Latif, Sarmad Dashti and Ehteram, Mohammad and Khozani, Zohreh Sheikh and Ahmed, Ali Najah and Sherif, Mohsen and El-Shafie, Ahmed (2024) An advanced hybrid deep learning model for predicting total dissolved solids and electrical conductivity (EC) in coastal aquifers. Environmental Sciences Europe, 36 (1). p. 20. ISSN 2190-4707, DOI https://doi.org/10.1186/s12302-024-00850-8 <https://doi.org/10.1186/s12302-024-00850-8>. https://doi.org/10.1186/s12302-024-00850-8 10.1186/s12302-024-00850-8 |
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TA Engineering (General). Civil engineering (General) Jamshidzadeh, Zahra Latif, Sarmad Dashti Ehteram, Mohammad Khozani, Zohreh Sheikh Ahmed, Ali Najah Sherif, Mohsen El-Shafie, Ahmed An advanced hybrid deep learning model for predicting total dissolved solids and electrical conductivity (EC) in coastal aquifers |
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For more than one billion people living in coastal regions, coastal aquifers provide a water resource. In coastal regions, monitoring water quality is an important issue for policymakers. Many studies mentioned that most of the conventional models were not accurate for predicting total dissolved solids (TDS) and electrical conductivity (EC) in coastal aquifers. Therefore, it is crucial to develop an accurate model for forecasting TDS and EC as two main parameters for water quality. Hence, in this study, a new hybrid deep learning model is presented based on Convolutional Neural Networks (CNNE), Long Short-Term Memory Neural Networks (LOST), and Gaussian Process Regression (GPRE) models. The objective of this study will contribute to the sustainable development goal (SDG) 6 of the united nation program which aims to guarantee universal access to clean water and proper sanitation. The new model can obtain point and interval predictions simultaneously. Additionally, features of data points can be extracted automatically. In the first step, the CNNE model automatically extracted features. Afterward, the outputs of CNNE were flattened. The LOST used flattened arrays for the point prediction. Finally, the outputs of the GPRE model receives the outputs of the LOST model to obtain the interval prediction. The model parameters were adjusted using the rat swarm optimization algorithm (ROSA). This study used PH, Ca + + , Mg2 + , Na + , K + , HCO3, SO4, and Cl- to predict EC and TDS in a coastal aquifer. For predicting EC, the CNNE-LOST-GPRE, LOST-GPRE, CNNE-GPRE, CNNE-LOST, LOST, and CNNE models achieved NSE values of 0.96, 0.95, 0.92, 0.91, 0.90, and 0.87, respectively. Sodium adsorption ratio, EC, magnesium hazard ratio, sodium percentage, and total hardness indices were used to evaluate the quality of GWL. These indices indicated poor groundwater quality in the aquifer. This study shows that the CNNE-LOST-GPRE is a reliable model for predicting complex phenomena. Therefore, the current developed hybrid model could be used by private and public water sectors for predicting TDS and EC for enhancing water quality in coastal aquifers. |
| format |
Article |
| author |
Jamshidzadeh, Zahra Latif, Sarmad Dashti Ehteram, Mohammad Khozani, Zohreh Sheikh Ahmed, Ali Najah Sherif, Mohsen El-Shafie, Ahmed |
| author_facet |
Jamshidzadeh, Zahra Latif, Sarmad Dashti Ehteram, Mohammad Khozani, Zohreh Sheikh Ahmed, Ali Najah Sherif, Mohsen El-Shafie, Ahmed |
| author_sort |
Jamshidzadeh, Zahra |
| title |
An advanced hybrid deep learning model for predicting total dissolved solids and electrical conductivity (EC) in coastal aquifers |
| title_short |
An advanced hybrid deep learning model for predicting total dissolved solids and electrical conductivity (EC) in coastal aquifers |
| title_full |
An advanced hybrid deep learning model for predicting total dissolved solids and electrical conductivity (EC) in coastal aquifers |
| title_fullStr |
An advanced hybrid deep learning model for predicting total dissolved solids and electrical conductivity (EC) in coastal aquifers |
| title_full_unstemmed |
An advanced hybrid deep learning model for predicting total dissolved solids and electrical conductivity (EC) in coastal aquifers |
| title_sort |
advanced hybrid deep learning model for predicting total dissolved solids and electrical conductivity (ec) in coastal aquifers |
| publisher |
Springer |
| publishDate |
2024 |
| url |
http://eprints.um.edu.my/45726/ https://doi.org/10.1186/s12302-024-00850-8 |
| _version_ |
1816130450138071040 |
| score |
13.214268 |