Projects per year
Abstract
Monitoring ex-situ water parameters, namely heavy metals, needs time and laboratory work for water sampling and analytical processes, which can retard the response to ongoing pollution events. Previous studies have successfully applied fast modeling techniques such as artificial intelligence algorithms to predict heavy metals. However, neither low-cost feature predictability nor explainability assessments have been considered in the modeling process. This study proposes a reliable and explainable framework to find an effective model and feature set to predict heavy metals in groundwater. The integrated assessment framework has four steps: model selection uncertainty, feature selection uncertainty, predictive uncertainty, and model interpretability. The results show that Random Forest is the most suitable model, and quick-measure parameters can be used as predictors for arsenic (As), iron (Fe), and manganese (Mn). Although the model performance is auspicious, it likely produces significant uncertainties. The findings also demonstrate that arsenic is related to nutrients and spatial distribution, while Fe and Mn are affected by spatial distribution and salinity. Some limitations and suggestions are also discussed to improve the prediction accuracy and interpretability.
Original language | English |
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Article number | 12180 |
Journal | International Journal of Environmental Research and Public Health |
Volume | 19 |
Issue number | 19 |
DOIs | |
State | Published - Oct 2022 |
Keywords
- Random Forest
- explainable artificial intelligence (XAI)
- groundwater quality
- heavy metals
- prediction intervals
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Dive into the research topics of 'Predicting Heavy Metal Concentrations in Shallow Aquifer Systems Based on Low-Cost Physiochemical Parameters Using Machine Learning Techniques'. Together they form a unique fingerprint.Projects
- 4 Finished
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Innovative Monitoring, Analysis Technologies, and Management Strategies for Mitigation of Land Subsidence
Chang, P.-Y. (PI)
1/08/20 → 31/07/21
Project: Research
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Trans-Disciplinary Research on Characterizing Spatio-Temporal Variations of Critical Zones in Taoyuan Tableland and Coastal Areas
Ni, C.-F. (PI)
1/08/20 → 31/07/21
Project: Research