Representing chemical history in ozone time-series predictions – a model experiment study building on the MLAir (v1.5) deep learning framework

Kleinert, Felix; Leufen, Lukas Hubert; Lupaşcu, Aurelia; Butler, Tim; Schultz, Martin

doi:10.5194/gmd-15-8913-2022

Cited by 4 publications

(3 citation statements)

References 67 publications

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“…These architectures could be trained to take transport and advection of air pollutants into account by incorporating wind directions. 19 One promising approach is also to infer the graph from the underlying data set. 47,71 To further explore how the graph structure affects the results and what parameters are most crucial, sensitivity studies are necessary.…”

Section: ■ Resultsmentioning

confidence: 99%

“…More sophisticated approaches that should be explored in the future include time-resolved graphs for spatiotemporal machine learning or transformer architectures, which can learn to attend to the most helpful features in unstructured data. These architectures could be trained to take transport and advection of air pollutants into account by incorporating wind directions . One promising approach is also to infer the graph from the underlying data set. , To further explore how the graph structure affects the results and what parameters are most crucial, sensitivity studies are necessary.…”

Section: Discussionmentioning

confidence: 99%

“…Missing data also impede the usefulness of such data in other contexts. For example, machine learning models to forecast ozone concentrations − require a gap-free time series as input to make predictions. It is therefore necessary to impute the gaps in the ozone concentrations.…”

Section: Introductionmentioning

confidence: 99%

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Graph Machine Learning for Improved Imputation of Missing Tropospheric Ozone Data

Betancourt,

Li,

Kleinert

et al. 2023

Environ. Sci. Technol.

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Gaps in the measurement series of atmospheric pollutants can impede the reliable assessment of their impacts and trends. We propose a new method for missing data imputation of the air pollutant tropospheric ozone by using the graph machine learning algorithm “correct and smooth”. This algorithm uses auxiliary data that characterize the measurement location and, in addition, ozone observations at neighboring sites to improve the imputations of simple statistical and machine learning models. We apply our method to data from 278 stations of the year 2011 of the German Environment Agency (Umweltbundesamt – UBA) monitoring network. The preliminary version of these data exhibits three gap patterns: shorter gaps in the range of hours, longer gaps of up to several months in length, and gaps occurring at multiple stations at once. For short gaps of up to 5 h, linear interpolation is most accurate. Longer gaps at single stations are most effectively imputed by a random forest in connection with the correct and smooth. For longer gaps at multiple stations, the correct and smooth algorithm improved the random forest despite a lack of data in the neighborhood of the missing values. We therefore suggest a hybrid of linear interpolation and graph machine learning for the imputation of tropospheric ozone time series.

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Section: ■ Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Graph Machine Learning for Improved Imputation of Missing Tropospheric Ozone Data

Betancourt,

Li,

Kleinert

et al. 2023

Environ. Sci. Technol.

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Forecasting of ozone concentrations using the Neural Prophet model: application to the Tunisian case

Chérif,

Snoun,

Bellakhal

et al. 2023

Euro-Mediterr J Environ Integr

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Regression analysis of air pollution and pediatric respiratory diseases based on interpretable machine learning

Zhi²,

Wu³

et al. 2023

Front. Earth Sci.

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Air pollution is of high relevance to human health. In this study, multiple machine-learning (ML) models—linear regression, random forest (RF), AdaBoost, and neural networks (NNs)—were used to explore the potential impacts of air-pollutant concentrations on the incidence of pediatric respiratory diseases in Taizhou, China. A number of explainable artificial intelligence (XAI) methods were further applied to analyze the model outputs and quantify the feature importance. Our results demonstrate that there are significant seasonal variations both in the numbers of pediatric respiratory outpatients and the concentrations of air pollutants. The concentrations of NO2, CO, and particulate matter (PM10 and PM2.5), as well as the numbers of outpatients, reach their peak values in the winter. This indicates that air pollution is a major factor in pediatric respiratory diseases. The results of the regression models show that ML methods can capture the trends and turning points of clinic visits, and the non-linear models were superior to the linear ones. Among them, the RF model served as the best-performing model. The analysis on the RF model by XAI found that AQI, O3, PM10, and the current month are the most important predictors affecting the numbers of pediatric respiratory outpatients. This shows that the number of outpatients rises with an increasing AQI, especially with the increasing of particulate matter. Our study indicates that ML models with XAI methods are promising for revealing the underlying impacts of air pollution on the pediatric respiratory diseases, which further assists the health-related decision-making.

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Representing chemical history in ozone time-series predictions – a model experiment study building on the MLAir (v1.5) deep learning framework

Cited by 4 publications

References 67 publications

Graph Machine Learning for Improved Imputation of Missing Tropospheric Ozone Data

Graph Machine Learning for Improved Imputation of Missing Tropospheric Ozone Data

Forecasting of ozone concentrations using the Neural Prophet model: application to the Tunisian case

Regression analysis of air pollution and pediatric respiratory diseases based on interpretable machine learning

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