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Autores principales: Du, Shangjie, Wei, Hui, Lee, Dong Yoon, Hu, Zhizhang, Pan, Shijia
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2506.06917
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author Du, Shangjie
Wei, Hui
Lee, Dong Yoon
Hu, Zhizhang
Pan, Shijia
author_facet Du, Shangjie
Wei, Hui
Lee, Dong Yoon
Hu, Zhizhang
Pan, Shijia
contents This work introduces GraPhy, a graph-based, physics-guided learning framework for high-resolution and accurate air quality modeling in urban areas with limited monitoring data. Fine-grained air quality monitoring information is essential for reducing public exposure to pollutants. However, monitoring networks are often sparse in socioeconomically disadvantaged regions, limiting the accuracy and resolution of air quality modeling. To address this, we propose a physics-guided graph neural network architecture called GraPhy with layers and edge features designed specifically for low-resolution monitoring data. Experiments using data from California's socioeconomically disadvantaged San Joaquin Valley show that GraPhy achieves the overall best performance evaluated by mean squared error (MSE), mean absolute error (MAE), and R-square value (R2), improving the performance by 9%-56% compared to various baseline models. Moreover, GraPhy consistently outperforms baselines across different spatial heterogeneity levels, demonstrating the effectiveness of our model design.
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publishDate 2025
record_format arxiv
spellingShingle Graph-Based Physics-Guided Urban PM2.5 Air Quality Imputation with Constrained Monitoring Data
Du, Shangjie
Wei, Hui
Lee, Dong Yoon
Hu, Zhizhang
Pan, Shijia
Machine Learning
Artificial Intelligence
This work introduces GraPhy, a graph-based, physics-guided learning framework for high-resolution and accurate air quality modeling in urban areas with limited monitoring data. Fine-grained air quality monitoring information is essential for reducing public exposure to pollutants. However, monitoring networks are often sparse in socioeconomically disadvantaged regions, limiting the accuracy and resolution of air quality modeling. To address this, we propose a physics-guided graph neural network architecture called GraPhy with layers and edge features designed specifically for low-resolution monitoring data. Experiments using data from California's socioeconomically disadvantaged San Joaquin Valley show that GraPhy achieves the overall best performance evaluated by mean squared error (MSE), mean absolute error (MAE), and R-square value (R2), improving the performance by 9%-56% compared to various baseline models. Moreover, GraPhy consistently outperforms baselines across different spatial heterogeneity levels, demonstrating the effectiveness of our model design.
title Graph-Based Physics-Guided Urban PM2.5 Air Quality Imputation with Constrained Monitoring Data
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2506.06917