An automatic detection of green tide using multi-windows with their adaptive threshold from Landsat TM/ETM plus image
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摘要: 大气校正是遥感影像绿潮检测之前必要的预处理步骤,大气校正所引入的误差直接影响绿潮检测结果的精度。为了消除大气校正给绿潮检测结果带来的误差,本文以Landsat影像为数据源,基于获取的绿潮爆发期影像与现场调查绿潮爆发范围的历史资料,分析得出Landsat影像中绿潮爆发区域与背景海水之间的光谱差异,发现绿潮与海水两者之间的分类阈值y与影像光谱差x=band (red)-band (nir)之间的存在线性关系y=0.723x+0.504,利用这一关系可实现Landsat影像绿潮自动检测;考虑到同一景影像不同区域之间存在亮度差异,本文将影像划分为多个同样大小的窗口,对每一窗口的自适应确定检测阈值,用以提高绿潮检测精度;实验发现,对于绿潮密度较大或云覆盖较严重的窗口区域,绿潮检测结果存在较大误差,虚警率较高,针对这一问题,本文提出窗口滑动步长k小于窗口宽度n的检测思路,对大部分检测点均会检测[n/k]*[n/k]次,最后采用投票的方式确定绿潮爆发区域。实验结果可以看出,本文提出的绿潮Landsat影像滑动窗口自适应阈值投票自动检测方法较传统的FAI和NDVI检测方法有所提高,而且避免了对大气校正处理精度的依赖。
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关键词:
- 自动检测 /
- 绿潮 /
- 自适应阈值 /
- LandsatTM/ETM+影像
Abstract: Since the atmospheric correction is a necessary preprocessing step of remote sensing image before detecting green tide, the introduced error directly affects the detection precision. Therefore, the detection method of green tide is presented from Landsat TM/ETM plus image which needs not the atmospheric correction. In order to achieve an automatic detection of green tide, a linear relationship (y=0.723x+0.504) between detection threshold y and subtraction x (x=λnir-λred) is found from the comparing Landsat TM/ETM plus image with the field surveys. Using this relationship, green tide patches can be detected automatically from Landsat TM/ETM plus image. Considering there is brightness difference between different regions in an image, the image will be divided into a plurality of windows (sub-images) with a same size firstly, and then each window will be detected using an adaptive detection threshold determined according to the discovered linear relationship. It is found that big errors will appear in some windows, such as those covered by clouds seriously. To solve this problem, the moving step k of windows is proposed to be less than the window width n. Using this mechanism, most pixels will be detected[n/k]×[n/k] times except the boundary pixels, then every pixel will be assigned the final class (green tide or sea water) according to majority rule voting strategy. It can be seen from the experiments, the proposed detection method using multi-windows and their adaptive thresholds can detect green tide from Landsat TM/ETM plus image automatically. Meanwhile, it avoids the reliance on the accurate atmospheric correction.-
Key words:
- automatic detection /
- green tide /
- adaptive threshold /
- Landsat TM/ETM plus image
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Bao Min, Guan Weibing, Wang Zongling, et al. 2015. Features of the physical environment associated with green tide in the southwestern Yellow Sea during spring. Acta Oceanologica Sinica, 34(7):97-104 Hu Chuanmin. 2009. A novel ocean color index to detect floating algae in the global oceans. Remote Sensing of Environmen, 113:2118-2129 Hu Song, Yang Hong, Zhang Jianheng, et al. 2014. Small-scale early aggregation of green tide macroalgae observed on the Subei Bank, Yellow Sea. Marine Pollution Bulletin, 81:166-173 Keesing J K, Liu D Y, Fearns P, et al. 2011. Inter-and intra-annual patterns of Ulva prolifera green macroalgaes in the Yellow Sea during 2007–2009, their origin and relationship to the expansion of coastal seaweed aquaculture in China. Marine Pollution Bulletin, 62:1169-1182 Liu D Y, Keesing J K, He P M, et al. 2013. The world's largest macroalgal bloom in the Yellow Sea, China:formation and implications. Estuar Coast Shelf Sci, 129:2-10 Lyons D A, Arvanitidis C, Blight A J, et al. 2014. Macroalgal blooms alter community structure and primary productivity in marine ecosystems. Global Change Biology, 20:2712-2724 Merceron M, Antoine V, Auby I, et al. 2007. In situ growth potenial of the subtidal part of green tide forming Ulva spp. Stocks. Since of The Total Environment, 384:293-305 Nelson T A, Haberlin K, Nelson A V, et al. 2008. Ecological and physiological controls of species composition in green macroalgal blooms. Ecology, 89:1287-1298 Smetacek W, Zingone A. 2013. Green and golden seaweed tides on the rise. Natrue, 504:84-88 Ye Naihao, Zhang Xiaowen, Mao Yuze, et al. 2011. "Green tides" are overwhelming the coastline of our blue planet:taking the world's largest example. Ecological Research, 26:477-485 Zhang Qingchun, Liu Qing, Yu Rencheng, et al. 2015. Application of a fluorescence in situ hybridization (FISH) method to study green tide in the Yellow Sea. Estuarine, Coastal and Shelf Science, 163:112-119 Zhou Mingjiang, Liu Dongyan, Donal M, et al. 2015. Introduction to the special issue on green tides in the Yellow Sea. Estuarine, Coastal and Shelf Science, 163:3-8
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