Utility-based regression and meta-learning techniques for modeling actual ET: Comparison to (METRIC-EEFLUX) model
Estimating actual evapotranspiration (ETₐ) is crucial for water resource management, yet existing methods face limitations. Traditional approaches, including eddy covariance and remote sensing-based energy balance methods, often struggle with high costs, limited spatial and temporal coverage, and re...
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| Format: | Article |
| Language: | English |
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KeAi Communications Co., Ltd.
2024-12-01
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| Series: | Artificial Intelligence in Agriculture |
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| Online Access: | http://www.sciencedirect.com/science/article/pii/S2589721724000400 |
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| author | Fatima K. Abu Salem Sara Awad Yasmine Hamdar Samer Kharroubi Hadi Jaafar |
| author_facet | Fatima K. Abu Salem Sara Awad Yasmine Hamdar Samer Kharroubi Hadi Jaafar |
| author_sort | Fatima K. Abu Salem |
| collection | DOAJ |
| description | Estimating actual evapotranspiration (ETₐ) is crucial for water resource management, yet existing methods face limitations. Traditional approaches, including eddy covariance and remote sensing-based energy balance methods, often struggle with high costs, limited spatial and temporal coverage, and reduced predictive accuracy, particularly for classical empirical models. While machine learning has emerged as a promising alternative, it still presents challenges, notably in underestimating ETₐ during periods of high heat. We attribute this to insufficient learning on the rare but highly relevant ETₐ values of interest, or the not-so-big climatic datasets available for use. In this manuscript, we demonstrate how few-shot, meta-learning models (MAML) that are specifically designed for enhanced generalizability on not-so-big datasets can outperform basic machine learning models in upscaling ETₐ from two major in-situ towers, the Ameriflux and Euroflux. Using limited remotely sensed land surface data from the METRIC-EEFlux and limited climatic variables, we demonstrate that the chosen models can attain quantifiable utility within the utility-based-regression paradigm towards impactful practical considerations. Our initial explorations reveal that EEflux ETₐ deviates significantly from in-situ observations measured through the Ameriflux and EEflux towers (R2=39%). Instead, MAML shows best performance in approximating ETₐ than basic machine learning algorithms and EEFlux (R2=71% on entire testing dataset, R2=0.88 on the Csa climate, R2=0.79 on the Cfa climate, and R2=0.78 on the CSH vegetation class), and continues to improve without overfitting even when exposed to a relatively small training dataset. Its high F2 score (96 %) indicates that MAML has very high precision and recall for rare cases, which is significant for irrigation. Of independent interest, this study confirms that limited remotely sensed EEflux products contribute significantly to knowledge about ground truth ETₐ and can thus be of valuable use in settings where access to good quality and high-volume data is compromised. |
| format | Article |
| id | doaj-art-61541f1ba7074d68a01961acb3b1b754 |
| institution | Kabale University |
| issn | 2589-7217 |
| language | English |
| publishDate | 2024-12-01 |
| publisher | KeAi Communications Co., Ltd. |
| record_format | Article |
| series | Artificial Intelligence in Agriculture |
| spelling | doaj-art-61541f1ba7074d68a01961acb3b1b7542024-12-14T06:31:54ZengKeAi Communications Co., Ltd.Artificial Intelligence in Agriculture2589-72172024-12-01144355Utility-based regression and meta-learning techniques for modeling actual ET: Comparison to (METRIC-EEFLUX) modelFatima K. Abu Salem0Sara Awad1Yasmine Hamdar2Samer Kharroubi3Hadi Jaafar4Department of Computer Science, Faculty of Arts and Sciences, American University of Beirut, Beirut, LebanonDepartment of Computer Science, Faculty of Arts and Sciences, American University of Beirut, Beirut, LebanonDepartment of Computer Science, Faculty of Arts and Sciences, American University of Beirut, Beirut, LebanonDepartment of Nutrition and Food Sciences, Faculty of Agricultural and Food Sciences, American University of Beirut, Beirut, LebanonDepartment of Agriculture, Faculty of Agricultural and Food Sciences, American University of Beirut, Beirut, Lebanon; Corresponding author.Estimating actual evapotranspiration (ETₐ) is crucial for water resource management, yet existing methods face limitations. Traditional approaches, including eddy covariance and remote sensing-based energy balance methods, often struggle with high costs, limited spatial and temporal coverage, and reduced predictive accuracy, particularly for classical empirical models. While machine learning has emerged as a promising alternative, it still presents challenges, notably in underestimating ETₐ during periods of high heat. We attribute this to insufficient learning on the rare but highly relevant ETₐ values of interest, or the not-so-big climatic datasets available for use. In this manuscript, we demonstrate how few-shot, meta-learning models (MAML) that are specifically designed for enhanced generalizability on not-so-big datasets can outperform basic machine learning models in upscaling ETₐ from two major in-situ towers, the Ameriflux and Euroflux. Using limited remotely sensed land surface data from the METRIC-EEFlux and limited climatic variables, we demonstrate that the chosen models can attain quantifiable utility within the utility-based-regression paradigm towards impactful practical considerations. Our initial explorations reveal that EEflux ETₐ deviates significantly from in-situ observations measured through the Ameriflux and EEflux towers (R2=39%). Instead, MAML shows best performance in approximating ETₐ than basic machine learning algorithms and EEFlux (R2=71% on entire testing dataset, R2=0.88 on the Csa climate, R2=0.79 on the Cfa climate, and R2=0.78 on the CSH vegetation class), and continues to improve without overfitting even when exposed to a relatively small training dataset. Its high F2 score (96 %) indicates that MAML has very high precision and recall for rare cases, which is significant for irrigation. Of independent interest, this study confirms that limited remotely sensed EEflux products contribute significantly to knowledge about ground truth ETₐ and can thus be of valuable use in settings where access to good quality and high-volume data is compromised.http://www.sciencedirect.com/science/article/pii/S2589721724000400EvapotranspirationMachine learningArtificial intelligenceEEFlux |
| spellingShingle | Fatima K. Abu Salem Sara Awad Yasmine Hamdar Samer Kharroubi Hadi Jaafar Utility-based regression and meta-learning techniques for modeling actual ET: Comparison to (METRIC-EEFLUX) model Artificial Intelligence in Agriculture Evapotranspiration Machine learning Artificial intelligence EEFlux |
| title | Utility-based regression and meta-learning techniques for modeling actual ET: Comparison to (METRIC-EEFLUX) model |
| title_full | Utility-based regression and meta-learning techniques for modeling actual ET: Comparison to (METRIC-EEFLUX) model |
| title_fullStr | Utility-based regression and meta-learning techniques for modeling actual ET: Comparison to (METRIC-EEFLUX) model |
| title_full_unstemmed | Utility-based regression and meta-learning techniques for modeling actual ET: Comparison to (METRIC-EEFLUX) model |
| title_short | Utility-based regression and meta-learning techniques for modeling actual ET: Comparison to (METRIC-EEFLUX) model |
| title_sort | utility based regression and meta learning techniques for modeling actual et comparison to metric eeflux model |
| topic | Evapotranspiration Machine learning Artificial intelligence EEFlux |
| url | http://www.sciencedirect.com/science/article/pii/S2589721724000400 |
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