A two-stage deep learning architecture for detection global coastal and offshore submesoscale ocean eddy using SDGSAT-1 multispectral imagery

IF 5.7 Q1 ENVIRONMENTAL SCIENCES Science of Remote Sensing Pub Date : 2024-11-02 DOI:10.1016/j.srs.2024.100174
Linghui Xia , Baoxiang Huang , Ruijiao Li , Ge Chen
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Abstract

Submesoscale ocean eddies are essential oceanic phenomenon that control and influence the ocean energy cascade. Most existing eddy detection methods rely on low-resolution satellite altimeter data, which fail to capture submesoscale ocean features and oceanographic phenomena in shallow water. Introducing high-resolution multispectral data can alleviate these problems, yet it has been largely overlooked. A generalized and efficient deep learning architecture that combines developments in deep learning with Sustainable Development Goals Science Satellite 1 (SDGSAT-1) multispectral data from earth observations offers a potential pathway for more fine detection of ocean eddies. Considering that oceanic eddy exhibits spatially sparse characteristics on high-resolution remote sensing scenes, the oceanic eddy detection (OED) model suitable for global coastal and offshore regions is divided into two stages: eddy information judgment and eddy position determination. Correspondingly, SDGSAT-1 multispectral data from November 2021 to December 2022 were carried out to construct two submesoscale eddy datasets for training and testing each stage model. The union validation of multiple metrics demonstrates that the proposed OED model and its stage models achieve state-of-the-art (SOTA) performance, especially in optically complex coastal and offshore waters. We applied the model to real-world scenes captured by SDGSAT-1 in 2023, and found that the detected results were mainly located at the water depth below 200 m. The authenticity of the recognition results is validated using sea surface chlorophyll concentration, temperature, and topography data, indicating that the OED model has achieved remarkable effectiveness under various sea conditions. In addition, the temporal distributions and statistical characteristics of detected submesoscale eddies are analyzed over an extended period (November 2021 to November 2023). Finally, HISEA-2, Landsat-9, and Sentinel-2 served as testing grounds to validate the generalization of the proposed methodology, with experimental results demonstrating that the OED model possesses significant developmental potential for multi-source remote sensing data. This paper presents a comprehensive deep learning framework for the global-scale detection of submesoscale eddies and underscores the pivotal role of high-resolution multispectral imagery as an innovative data source for global coastal and offshore eddy identification.
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利用 SDGSAT-1 多光谱图像探测全球沿海和近海次主题尺度海洋漩涡的两阶段深度学习架构
次主题尺度海洋漩涡是控制和影响海洋能量级联的重要海洋现象。现有的漩涡探测方法大多依赖于低分辨率的卫星测高仪数据,无法捕捉浅水区的亚目尺度海洋特征和海洋学现象。引入高分辨率多光谱数据可以缓解这些问题,但却在很大程度上被忽视了。将深度学习的发展与对地观测的可持续发展目标科学卫星 1 号(SDGSAT-1)多光谱数据相结合的通用高效深度学习架构,为更精细地探测海洋漩涡提供了潜在的途径。考虑到海洋漩涡在高分辨率遥感场景中表现出空间稀疏的特征,适用于全球沿海和近海区域的海洋漩涡探测(OED)模型分为两个阶段:漩涡信息判断和漩涡位置确定。与此对应,利用 2021 年 11 月至 2022 年 12 月的 SDGSAT-1 多光谱数据,构建了两个亚目尺度漩涡数据集,用于训练和测试各阶段模型。多个指标的联合验证表明,所提出的 OED 模型及其阶段模型达到了最先进(SOTA)的性能,尤其是在光学复杂的沿岸和近海水域。我们将该模型应用于 2023 年 SDGSAT-1 拍摄的真实场景,发现检测结果主要位于 200 米以下的水深。此外,还分析了在一个较长时期内(2021 年 11 月至 2023 年 11 月)探测到的 submesoscale 涡的时间分布和统计特征。最后,以 HISEA-2、Landsat-9 和 Sentinel-2 为试验场,验证了所提方法的普适性,实验结果表明 OED 模型在多源遥感数据方面具有巨大的发展潜力。本文提出了一个全面的深度学习框架,用于全球尺度的次中尺度漩涡探测,并强调了高分辨率多光谱图像作为全球沿岸和近海漩涡识别的创新数据源的关键作用。
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