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Stacking Artificial Intelligence Models for Predicting Water Quality Parameters in Rivers

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Scrutinizing the changes in the quality of river water is one of the main factors of monitoring the quality of natural flows, which plays a crucial role in the sustainable management of these ecosystems. The concentration of dissolved oxygen (DO) in river water is one of the most important indicators of quality management in such water bodies. From an environmental point of view, exceeding the permissible and natural decay capacity of pollutants in natural streams leads to a decrease in DO and, consequently, causes serious risks for the survival of aquatic life in related ecosystems. Hence, in the present study, 10 daily variables with the amount of dissolved oxygen on the same day were collected and evaluated from Allen County. Moreover, half of these variables were chosen as effective inputs to the model based on statistical analysis, so as to calculate the dissolved oxygen concentration parameter. Modeling with artificial intelligence approaches was implemented in the form of four individual methods: ANFIS-PSO, OS-ELM, Bagging-RF and Boosting CART, and two ensemble-stacking methods: SMA and Meta-learner MLP. The outcomes of estimating the DO with RMSE, MAE, GRI, r, and MBE criteria and marginal-scatter and subject profile diagrams were discussed. Moreover, the efficiency of the models in estimating the outlier of the observational data was scrutinized by subject profile diagram. Finally, it was found that the Meta-learner MLP model with RMSE of 0.965 mg/L had improvement in performance by 8.8%, 8.9%, 22.3%, 24.9% and 27.6%, respectively, compared to SMA, Boosting CART, Bagging-RF, ANFIS-PSO and OS-ELM methods. This remarkable improvement led to recommendations for using stacking techniques in water quality modeling and simulation.
Rocznik
Strony
152--164
Opis fizyczny
Bibliogr. 38 poz., rys., tab.
Twórcy
  • Department of Civil Engineering, Faculty of Engineering – Rabigh Branch, King Abdulaziz University, Jeddah 21589, Saudi Arabia
  • Department of Civil Engineering, Faculty of Engineering – Rabigh Branch, King Abdulaziz University, Jeddah 21589, Saudi Arabia
Bibliografia
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  • 4. Bui D.T., Khosravi K., Tiefenbacher J., Nguyen H., Kazakis N. 2020. Improving prediction of water quality indices using novel hybrid machine-learning algorithms. Science of The Total Environment, 721, 137612.
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  • 9. Fadaee M., Mahdavi‐Meymand A., Zounemat‐Kermani M. 2020. Seasonal short‐term prediction of dissolved oxygen in rivers via nature‐inspired algorithms. CLEAN–Soil, Air, Water, 48(2), 1900300.
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  • 12. Haghiabi A.H., Nasrolahi A.H., Parsaie A. 2018. Water quality prediction using machine learning methods. Water Quality Research Journal, 53(1), 3–13.
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  • 19. Leong W.C., Bahadori A., Zhang J., Ahmad Z. 2021. Prediction of water quality index (WQI) using support vector machine (SVM) and least square-support vector machine (LS-SVM). International Journal of River Basin Management, 19(2), 149–156.
  • 20. Li J., Abdulmohsin H.A., Hasan S.S., Kaiming L., Al-Khateeb B., Ghareb M.I., Mohammed M.N. 2019. Hybrid soft computing approach for determining water quality indicator: Euphrates River. Neural Computing and Applications, 31(3), 827–837.
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  • 23. Lusiana E.D., Mahmudi M., Hutahaean S.M., Darmawan A., Buwono N.R., Arsad S., Musa M. 2022. A multivariate technique to develop hybrid water quality index of the Bengawan Solo River, Indonesia. Journal of Ecological Engineering, 23(2), 123–131.
  • 24. Najah A., Elshafie A., Karim O.A., Jaffar O. 2009. Prediction of Johor River water quality parameters using artificial neural networks. European Journal of Scientific Research, 28(3), 422–435.
  • 25. Najah A., El-Shafie A., Karim O.A., El-Shafie A.H. 2014. Performance of ANFIS versus MLP-NN dissolved oxygen prediction models in water quality monitoring. Environmental Science and Pollution Research, 21, 1658–1670.
  • 26. Pham Q.B., Mohammadpour R., Linh N.T.T., Mohajane M., Pourjasem A., Sammen S.S., Anh D.T., Nam V.T. 2021. Application of soft computing to predict water quality in wetland. Environmental Science and Pollution Research, 28(1), 185–200.
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  • 31. Shiri N., Shiri J., Yaseen Z.M., Kim S., Chung I.M., Nourani V., Zounemat-Kermani M. 2021. Development of artificial intelligence models for well groundwater quality simulation: Different modeling scenarios. Plos one, 16(5), e0251510.
  • 32. Singh K.P., Basant A., Malik A., Jain G. 2009. Artificial neural network modeling of the river water quality—A case study. Ecological Modelling, 220(6), 888–895.
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  • 34. Varol M. 2020. Use of water quality index and multivariate statistical methods for the evaluation of water quality of a stream affected by multiple stressors: A case study. Environmental Pollution, 266, 115417.
  • 35. Yu J.-W., Kim J.-S., Li X., Jong Y.-C., Kim K.-H., Ryang G.-I. 2022. Water quality forecasting based on data decomposition, fuzzy clustering and deep learning neural network. Environmental Pollution, 303, 119136.
  • 36. Zounemat-Kermani M., Seo Y., Kim S., Ghorbani M.A., Samadianfard S., Naghshara S., Kim N.W., Singh V.P. 2019. Can decomposition approaches always enhance soft computing models? Predicting the dissolved oxygen concentration in the St. Johns River, Florida. Applied Sciences, 9(12), 2534.
  • 37. Zounemat-Kermani M., Batelaan O., Fadaee M., Hinkelmann R. 2021a. Ensemble machine learning paradigms in hydrology: A review. Journal of Hydrology, 598, 126266.
  • 38. Zounemat-Kermani M., Alizamir M., Fadaee M., Sankaran Namboothiri A., Shiri J. 2021b. Online sequential extreme learning machine in river water quality (turbidity) prediction: A comparative study on different data mining approaches. Water and Environment Journal, 35(1), 335–348.
Uwagi
Opracowanie rekordu ze środków MEiN, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2022-2023).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-ae21da18-a9a2-4e85-896e-c1040d709bcc
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