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利用深度学习和合成孔径雷达(SAR)卫星数据对苏伊士运河北入口进行自动溢油检测。

Automated oil spill detection using deep learning and SAR satellite data for the northern entrance of the Suez Canal.

作者信息

Zakzouk Mohamed, Abdulaziz Abdulaziz M, Abou El-Magd Islam, Dahab Abdel Sattar, Ali Elham M

机构信息

Mining, Petroleum, and Metallurgical Engineering Department, Faculty of Engineering, Cairo University, Giza, Egypt.

Environment Division, National Authority for Remote Sensing and Space Sciences, Cairo, Egypt.

出版信息

Sci Rep. 2025 Jun 20;15(1):20107. doi: 10.1038/s41598-025-03028-1.

DOI:10.1038/s41598-025-03028-1
PMID:40541995
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12181334/
Abstract

Oil spills threaten marine ecosystems, demanding swift detection and response. The northern entrance of the Suez Canal, a critical maritime route, is increasingly at risk of frequent oil spill incidents. This study employs the DeepLabv3 + deep learning model to automatically detect oil spills in the study area based on Sentinel-1 Synthetic Aperture Radar imagery provided by the European Space Agency. The model was trained separately on two datasets: the European Maritime Safety Agency CleanSeaNet (EMSA-CSN) dataset, comprising 1100 oil spill incidents, and a localized dataset containing 1500 oil spill incidents that occurred at the Egyptian territorial waters. A comparative analysis between the two models was conducted using 30 oil spill test cases located within the study area. The model trained on Egyptian data outperformed the EMSA-CSN-data- trained model, achieving a loss of 0.0516, an accuracy of 98.14%, a mean Intersection over Union (MIoU) of 0.7872, and a significantly higher ROC area of 0.91, compared to a loss of 0.1152, an accuracy of 96.45%, a MIoU of 0.7161, and a ROC area of 0.76 for the EMSA-CSN model. In addition, the area prediction analysis confirmed the superior performance of the Egyptian-data-trained model, which estimated a total affected area of 421.20 km, closely aligning with the ground truth of 425.20 km, whereas the EMSA-CSN-data-trained model underestimated oil spills of around 323.98 km. These results highlight the benefits of region-specific training in improving segmentation quality and reducing errors. This study emphasizes the potential of AI-driven models for real-time oil spill monitoring, with applications in environmental protection and emergency response.

摘要

石油泄漏威胁着海洋生态系统,需要迅速进行检测和应对。苏伊士运河的北入口是一条重要的海上航线,频繁发生石油泄漏事故的风险越来越大。本研究采用DeepLabv3 +深度学习模型,基于欧洲航天局提供的哨兵-1合成孔径雷达图像,自动检测研究区域内的石油泄漏。该模型在两个数据集上分别进行训练:欧洲海事安全局清洁海洋网络(EMSA-CSN)数据集,包含1100起石油泄漏事故;以及一个本地化数据集,包含发生在埃及领海的1500起石油泄漏事故。使用研究区域内的30个石油泄漏测试案例对两个模型进行了对比分析。在埃及数据上训练的模型优于在EMSA-CSN数据上训练的模型,损失为0.0516,准确率为98.14%,平均交并比(MIoU)为0.7872,ROC面积显著更高,为0.91;相比之下,EMSA-CSN模型的损失为0.1152,准确率为96.45%,MIoU为0.7161,ROC面积为0.76。此外,面积预测分析证实了在埃及数据上训练的模型具有更好的性能,该模型估计的总受影响面积为421.20平方公里,与地面真值425.20平方公里非常接近,而在EMSA-CSN数据上训练的模型低估了约323.98平方公里的石油泄漏面积。这些结果突出了针对特定区域进行训练在提高分割质量和减少误差方面的好处。本研究强调了人工智能驱动的模型在实时石油泄漏监测方面的潜力,可应用于环境保护和应急响应。

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