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基于AUNet++的Sentinel-1/SAR辽东湾海冰检测方法研究

郑斌 石立坚 邹斌 任鹏 曾韬 孙晓煜 张蔡辉

郑斌,石立坚,邹斌,等. 基于AUNet++的Sentinel-1/SAR辽东湾海冰检测方法研究[J]. 海洋学报,2024,46(10):108–119 doi: 10.12284/hyxb2024097
引用本文: 郑斌,石立坚,邹斌,等. 基于AUNet++的Sentinel-1/SAR辽东湾海冰检测方法研究[J]. 海洋学报,2024,46(10):108–119 doi: 10.12284/hyxb2024097
Zheng Bin,Shi Lijian,Zou bin, et al. Research on Sentinel-1/SAR sea ice detection method in Liaodong Bay based on AUNet++[J]. Haiyang Xuebao,2024, 46(10):108–119 doi: 10.12284/hyxb2024097
Citation: Zheng Bin,Shi Lijian,Zou bin, et al. Research on Sentinel-1/SAR sea ice detection method in Liaodong Bay based on AUNet++[J]. Haiyang Xuebao,2024, 46(10):108–119 doi: 10.12284/hyxb2024097

基于AUNet++的Sentinel-1/SAR辽东湾海冰检测方法研究

doi: 10.12284/hyxb2024097
基金项目: 国家重点研发计划项目2022YFC2807003,2021YFC2803300。
详细信息
    作者简介:

    郑斌(1998—),男,山东省安丘市人,研究生,主要研究方向为深度学习与遥感图像处理,E-mail:1981611812@qq.com

    通讯作者:

    石立坚(1981—),男,山东省泰安人,研究员,硕士生导师,主要研究方向为海洋遥感应用,E-mail:shilj@mail.nsoas.org.cn

  • 中图分类号: P731.32

Research on Sentinel-1/SAR sea ice detection method in Liaodong Bay based on AUNet++

  • 摘要: 冬季海冰会极大影响辽东湾地区近岸工程建筑、石油平台、船舶航行等安全生产活动。星载合成孔径雷达不受天气影响且分辨率高,可用于辽东湾海冰灾害监测。本文在深度学习模型UNet++的基础上引入卷积注意力模块(CBAM),并使用交叉损失函数来优化模型,建立辽东湾Sentinel-1 SAR图像高精度海冰检测模型(AUNet++),并与PSPNet、Deeplabv3+、DAU-Net等多种深度学习方法进行对比。实验结果表明AUNet++海冰检测方法在OA、AA、MIoU、Kappa系数4种指标上分别达到了97.56%、97.53%、95.19%、95.07%,结果优于其他深度学习方法。该方法可以在高风速的干扰下对海冰边缘、光滑冰面完成精确海冰信息提取,能够为辽东湾地区的大范围、高精度海冰检测工作提供技术支撑。
  • 图  1  研究区域地理位置(渤海辽东湾)

    Fig.  1  The geographical location of the study area (Liaodong Bay, Bohai Sea)

    图  2  数据预处理前后对比

    a. VV极化,b. RGB假彩色

    Fig.  2  Comparison before and after data preprocessing

    a. VV band, b. RGB false color

    图  3  样本切片与对应标签

    Fig.  3  Sample data with corresponding labels

    图  4  AUNet++ 整体架构

    Fig.  4  Overall architecture of AUNet++

    图  6  各类样本不同方法结果可视化

    a. 冰水间隙,b. 光滑冰面,c. 碎冰,d. 海冰边缘,e. 高风速区域

    Fig.  6  Visualization of results of different methods for various samples

    a. ice water gap, b. smooth ice surface, c. broken ice, d. sea ice margin, e. high wind speed area

    图  5  CBAM模块(绿框为通道注意力模块,紫框为空间注意力模块)[19]

    Fig.  5  CBAM module (green box is channel attention module and purple box is space attention module)[19]

    图  7  消融实验可视化结果

    Fig.  7  Visualization results of ablation experiments

    图  8  重叠灰度区域

    Fig.  8  Overlapping gray area

    图  9  切片拼接过程(未进行像素重叠处理)

    Fig.  9  Slice splicing process (without pixel overlap processing)

    图  10  不同重叠区域处理方法结果对比

    Fig.  10  Comparison of the results of different overlapping region processing methods

    图  11  2020年辽东湾冰期3景Sentinel-1数据整体检测结果

    Fig.  11  Overall detection results of Sentinel-1 data of three views during the Liaodong Bay ice Age in 2020

    图  12  辽东湾3景Sentinel-1数据整体检测结果

    Fig.  12  Overall detection results of Sentinel-1 data of three views in Liaodong Bay

    表  1  研究数据具体参数信息

    Tab.  1  Specific parameter information of research data

    序号 成像时间 数据模式 极化方式 分辨率 卫星
    1 2019年12月9日09:49 IW VV+VH 5 × 20 m A星
    2 2020年1月2日09:49 IW VV+VH 5 × 20 m A星
    3 2020年1月8日09:48 IW VV+VH 5 × 20 m B星
    4 2020年1月14日09:48 IW VV+VH 5 × 20 m A星
    5 2020年1月20日09:48 IW VV+VH 5 × 20 m B星
    6 2020年1月26日09:49 IW VV+VH 5 × 20 m A星
    7 2020年2月1日09:48 IW VV+VH 5 × 20 m B星
    8 2020年2月7日09:49 IW VV+VH 5 × 20 m A星
    9 2020年2月13日09:48 IW VV+VH 5 × 20 m B星
    10 2020年2月19日09:49 IW VV+VH 5 × 20 m A星
    11 2023年2月3日09:49 IW VV+VH 5 × 20 m A星
    12 2024年1月5日09:49 IW VV+VH 5 × 20 m A星
    13 2024年1月17日09:49 IW VV+VH 5 × 20 m A星
    下载: 导出CSV

    表  2  不同方法对比结果

    Tab.  2  Comparison results of different methods

    方法总体精度/%平均精度/%均交并比/%Kappa系数/%
    SegNet96.6596.6893.4793.24
    PSPNet93.5793.5987.8484.05
    DeepLabv3+94.4894.5092.9492.67
    UNet96.4896.4993.1592.90
    DAU-UNet96.3796.3592.9492.67
    AUNet++97.5697.5395.1995.07
    下载: 导出CSV

    表  3  消融实验结果分析

    Tab.  3  Analysis of ablation results

    方法 总体精度/% 平均精度/% 均交并比/% Kappa系数
    UNet++ 97.17 97.17 94.46 94.30
    UNet++_BCED 97.23 97.24 94.57 94.41
    AUNet++ 97.37 97.35 94.83 94.69
    AUNet++_BCED 97.56 97.53 95.19 95.07
    下载: 导出CSV
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出版历程
  • 收稿日期:  2024-03-06
  • 修回日期:  2024-07-30
  • 网络出版日期:  2024-09-25
  • 刊出日期:  2024-10-30

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