Extraction of the raft aquaculture area based on convolutional neural networks and data fusion
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摘要: 准确提取海水筏式养殖区信息对于海洋资源管理和环境监测具有重要意义,但是筏式养殖区养殖筏因淹没于水中常出现数据弱信号区域的现象,导致仅凭光学影像提取精度较低。因此,本文以威海荣成湾为研究区域,通过添加通道注意力机制改进U-Net神经网络并结合高分2号光学影像光谱信息以及高分3号雷达影像纹理信息,尝试提高筏式养殖区提取精度。结果表明:(1)无论是对于单一的光学影像还是光学和雷达影像融合影像,添加通道注意力机制的U-Net神经网络预测结果总体精度都会提高,提高幅度在2.21%~4.12%之间。(2)利用改进后的U-Net神经网络处理融合数据,总体精度达到95.75%,相对于仅用高分2号影像的精度高4.3%;(3)对于弱信号区域,利用改进网络以及融合数据提取的总体精度和Kappa系数分别为91.61%和0.827 7。该方法可以对海洋筏式养殖区弱信号区域进行有效提取,能够为海洋养殖面积统计以及海洋环境检测提供技术支持。Abstract: Accurate extraction of marine raft aquaculture area information is of great significance for marine resource management and environmental monitoring. But the raft culture area is often submerged in water with weak data signal areas, resulting in low extraction accuracy based on optical images alone. Therefore, this paper takes Weihai Rongcheng Bay as the research area, and improves the U-Net neural network by adding channel attention mechanism to combine the spectral information of GF-2 optical image and the texture information of GF-3 radar image, trying to improve the extraction accuracy of raft aquaculture area. The results show that: (1) Whether it is a single optical image or a fusion image of optical and radar images, the overall accuracy of the prediction results of the U-Net neural network with channel attention mechanism will be improved, with an increase of 2.21%−4.12%. (2) Using the improved U-Net neural network to process the fusion data, the overall accuracy is 95.75%, which is 4.3% higher than that of only using GF-2 image. (3) For weak signal region, the overall accuracy and Kappa coefficient of extraction based on improved network and data fusion are 91.61% and 0.827 7, respectively. This method can effectively extract the weak signal area of marine raft aquaculture area, and can provide technical support for marine aquaculture area statistics and marine environment detection.
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Key words:
- raft aquaculture area /
- weak signal area /
- channel attention mechanism /
- U-Net /
- image fusion
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图 1 研究区
a. 研究区所在位置;b. 高分二号卫星影像;c. 高分三号卫星影像
Fig. 1 Study area
a. Location of the study area; b. GF-2 satellite image; c. GF-3 satellite image
图 3 采用通道注意力机制的U-Net神经网络结构
Fig. 3 U-Net neural network structure adopting channel attention mechanism
图 4 基于全局最大池化和平均池化的SE模块
Fig. 4 SE module based on global max pooling and average pooling
图 8 弱信号区域预测结果
a为原始影像;b为标签数据;c为GF2数据集预测结果;d为GF23S数据集预测结果;e为GF23B数据集预测结果
Fig. 8 Prediction results of weak signal areas
a: Original image; b: label image; c: prediction result of GF2 dataset; d: prediction result of GF23S dataset; e: prediction result of GF23B dataset
表 2 U-Net与SE_U-Net模型预测结果精度评估
Tab. 2 Evaluation of the extraction result for U-Net and SE_U-Net model
模型 GF2 GF23S GF23B U-Net 总体精度/% 85.30 87.47 91.33 Kappa系数 0.708 7 0.751 0 0.826 8 SE_U-Net 总体精度/% 89.42 89.68 93.71 Kappa系数 0.788 7 0.794 3 0.874 0 
下载: 导出CSV
表 3 不同数据集预测精度
Tab. 3 Prediction accuracy for different datasets
数据集 类别 召回率/
%精确率/
%错分
率/%漏分
率/%F1分数 GF2 背景 95.08 88.61 11.39 4.92 91.73 养殖区 80.54 91.14 8.86 19.46 85.51 GF23S 背景 97.11 93.78 6.22 2.89 95.42 养殖区 89.74 95.12 4.88 10.26 92.35 GF23B 背景 96.96 96.16 3.84 3.04 96.56 养殖区 93.84 95.10 4.90 6.16 94.50
下载: 导出CSV
表 4 不同数据集预测结果精度评估
Tab. 4 Evaluation of the extraction result for different datasets
数据集 总体精度/% Kappa系数 GF2 89.47 0.772 9 GF23S 94.27 0.877 7 GF23B 95.75 0.910 2
下载: 导出CSV
表 5 弱信号区域预测结果精度评估
Tab. 5 Evaluation of the extraction result of the weak signal areas
测试区 数据集 总体精度/% Kappa系数 Test1 GF2 81.41 0.6334 GF23S 84.75 0.6965 GF23B 91.61 0.8277 Test2 GF2 89.52 0.7463 GF23S 91.79 0.8052 GF23B 94.30 0.8717 Test3 GF2 82.40 0.6428 GF23S 88.18 0.7620 GF23B 91.59 0.8309
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