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Applying Deep Learning for Wildfire Identification: Economical and Accessible Solutions Leveraging Small Datasets
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Applying Deep Learning for Wildfire Identification: Economical and Accessible Solutions Leveraging Small Datasets
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Applying Deep Learning for Wildfire Identification: Economical and Accessible Solutions Leveraging Small Datasets
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Journal Article
Applying Deep Learning for Wildfire Identification: Economical and Accessible Solutions Leveraging Small Datasets
2025
Overview
Wildfires significantly impact human health, air quality, visibility, weather, and climate change and cause substantial economic losses. While state and county-operated air quality monitors provide critical insights during wildfires, they are not available in all regions. This highlights the need for affordable, accessible tools that allow the general public to assess air quality impacts. In this study, we apply machine learning with deep neural networks to diagnose air quality rapidly from sky images taken at the Pacific Northwest National Laboratory in Richland, WA, USA. Using a convolutional neural network (CNN) framework, we trained a deep learning model to classify air quality indices based on sky images. By leveraging transfer learning, our approach fine-tunes a pre-trained model on a small dataset of sky images, significantly reducing training time while maintaining high accuracy. Our results demonstrate the potential of deep learning to provide rapid air quality diagnostics during wildfire episodes, offering early warnings to the public and enabling timely mitigation strategies, particularly for vulnerable populations. Additionally, we show that lower respiratory infections pose the highest health risk during acute smoke exposures. Reactive oxygen species (ROS) from wildfire particles further exacerbate health risks by triggering inflammation and other adverse effects.
