核心概念
The development and application of a large, labeled satellite imagery dataset (CWGID) for training deep learning models to accurately detect forest wildfires.
摘要
The study presents the creation and application of the California Wildfire GeoImaging Dataset (CWGID), a high-resolution bi-temporal labeled satellite imagery dataset for deep learning-driven forest wildfire detection.
The dataset building process involves:
- Gathering and refining wildfire data from authoritative sources like the Fire and Resource Assessment Program (FRAP).
- Downloading Sentinel-2 satellite imagery from Google Earth Engine (GEE) for the identified wildfire locations and time periods.
- Creating ground truth masks by overlaying the satellite imagery with the wildfire perimeter data.
- Segmenting the imagery into 256x256 pixel tiles and applying data augmentation.
The resulting CWGID contains over 106,000 pairs of labeled before and after wildfire RGB GeoTIFF image tiles, with 29,082 positive instances of wildfire damage.
Three deep learning architectures - VGG16, Early Fusion (EF) EfficientNet-B0, and Siamese EfficientNet-B0 - are evaluated on the CWGID. The EF EfficientNet-B0 model achieves the highest accuracy of over 92% in detecting forest wildfires, outperforming the other approaches. The bi-temporal nature of the dataset allows this model to effectively capture changes between pre- and post-wildfire conditions.
The CWGID and the methodology used to build it prove to be a valuable resource for training and testing deep learning architectures for forest wildfire detection.
统计
The CWGID contains over 106,000 pairs of labeled before and after wildfire RGB GeoTIFF image tiles.
29,082 of the image pairs are positive instances of wildfire damage.
The EF EfficientNet-B0 model achieves an accuracy of over 92% in detecting forest wildfires.
引用
"The CWGID and the methodology used to build it, prove to be a valuable resource for training and testing DL architectures for forest wildfire detection."
"The bi-temporal nature of the dataset allows this model to effectively capture changes between pre- and post-wildfire conditions."