Automatic extraction of coastline by remote sensing technology based on SVM and auto-selection of training samples

doi:10.6046/gtzyyg.2013.02.13

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Abstract The timely and accurate automatic extraction of coastline from satellite remote sensing imagery is one of the important applications of remote sensing technology and has great significance for management planning of the sea area. Because the spectral characteristics of coastal water are susceptible to regional environment,the traditional method of normalized difference water index(NDWI)threshold segmentation may easily misclassify water as land in the process of separation of land and water, which will seriously affect the accuracy of shoreline extraction. In this paper,on the basis of NDWI model,the authors proposed an automatic coastline extraction method based on classification sample auto-selection and support vector machine(SVM). Firstly,through the NDWI calculation and global threshold segmentation,the initial water distribution information is obtained. And then,the classification samples are selected automatically under the control of NDWI information. Thirdly,the water are separated from the land by using SVM classifier. The last step is to fill small terrestrial water body units and track coastline automatically. The experimental results show that this method can effectively enhance the capability of coastal water identification and improve the accuracy and automation of the coastline extraction from remote sensing imager.

Keywords urban heat island central city proper land surface temperature spatial distribution cooling effect

TP751.1

Issue Date: 28 April 2013

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	LIU Dong
	LI Yan
	KONG Fanhua

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LIU Dong,LI Yan,KONG Fanhua. Automatic extraction of coastline by remote sensing technology based on SVM and auto-selection of training samples[J]. REMOTE SENSING FOR LAND & RESOURCES, 2013, 25(2): 69-74.

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https://www.gtzyyg.com/EN/10.6046/gtzyyg.2013.02.13 OR https://www.gtzyyg.com/EN/Y2013/V25/I2/69

[1] Ryan T W,Semintilli P J,Yuen P,et al.Extraction of shoreline features by neural nets and image processing[J].Photogrammetry and Remote Sensing,1991,57(7):947-955.
[2] Sohn H G,Jezek K C.Mapping ice sheet margins from ERS-1 SAR and SPOT imagery[J].International Journal of Remote Sensing,1999,20(15/16):3201-3216.
[3] Lee J S,Jurkevich I.Coastline detection and tracing in SAR images[J].IEEE Transactions on Geoscience and Remote Sensing,1990,28(4):662-668.
[4] 冯兰娣,孙效功,胥可辉.利用海岸带遥感图像提取岸线的小波变换方法[J].青岛海洋大学学报:自然科学版,2002,32(5):777-781. Feng L D,Sun X G,Xu K H.Edge detection of coastline based on wavelet transform method[J].Journal of Ocean University of Qingdao,2002,32(5):777-781.
[5] 霍继双,王超,王正志.一种基于多阈值的形态学提取遥感图象海岸线特征方法[J].中国图象图形学报,2003,8(7):805-809. Huo J S,Wang C,Wang Z Z.A multi-threshold based morphological approach for extracting coastal line feature from remote sensed images[J].Journal of Image and Graphics,2003,8(7):805-809.
[6] 张朝阳,冯伍法,张俊华.基于色差的遥感影像海岸线的提取[J].测绘学院学报,2005,22(4):259-262. Zhang C Y,Feng W F,Zhang J H.A coastline detection method based on the color difference for the RS image[J].Journal of Institute of Surveying and Mapping,2005,22(4):259-262.
[7] 王琳,徐涵秋,攀胜.厦门岛及其邻域海岸线变化的遥感动态监测[J].遥感技术与应用,2005,20(4):404-410. Wang L,Xu H Q,Pan S.Dynamic monitoring of the shoreline changes in Xiamen Island with its surrounding areas using remote sensing technology[J].Remote Sensing Technology and Application,2005,20(4):404-410.
[8] Liu H,Jezek K C.Automated extraction of coastline from satellite imagery by integrating canny edge detection and locally adaptive thresholding methods[J].International Journal of Remote Sensing,2004,25(5):937-958.
[9] Marfai M A,Almohammad H,Dey S, et al.Coastal dynamic and shoreline mapping:Multi-sources spatial data analysis in Semarang Indonesia[J].Environmental Monitoring and Assessment,2008,142(1/3):297-308.
[10] 冯永玖,韩震.海岸线遥感信息提取的元胞自动机方法及其应用[J].中国图象图形学报,2012,17(3):441-446. Feng Y J,Han Z.Cellular automata approach to extract shoreline from remote sensing imageries and its application[J].Journal of Image and Graphics,2012,17(3):441-446.
[11] 韩震,金亚秋.星载红外与微波多源遥感数据提取长江口淤泥质潮滩水边线信息[J].自然科学进展,2005,18(8):1000-1006. Han Z,Jing Y Q.The Yangtze Delta muddy tidal flat shoreline extraction based on multi-source remote sensing data of satellite infrared and microwave[J].Progress in Natural Science,2005,18(8):1000-1006.
[12] Niedermeier A,Lehner S,Van der,Sander J.Monitoring big river estuaries using SAR images[J].Geoscience and Remote Sensing Symposium,2001(4):1756-1758.
[13] 杜涛,张斌.用小波技术分析遥感图像确定岸线位置的研究[J].海洋科学,1999(4):19-20. Du T,Zhang B.A study of mapping coast by processing remote sensing image with wavelets[J].Marine Science,1999(4):19-20.
[14] 王李娟,牛铮,赵德刚,等.基于ETM遥感影像的海岸线提取与验证研究[J].遥感技术与应用,2010,25(2):235-239. Wang L J,Niu Z,Zhao D G,et al.The study of coastline extraction and validation using ETM remote sensing image[J].Remote Sensing Technology and Application,2010,25(2):235-239.
[15] Mason D C,Davenport I J.Accurate and efficient determination of the shoreline in ERS-1 SAR images[J].IEEE Transactions on Geoscience and Remote Sensing,1996,34(5):1243-1253.
[16] 朱小鸽.珠江口海岸线变化的遥感监测[J].海洋环境科学,2002,21(2):19-22. Zhu X G.Remote sensing monitoring of coastline changes in Pearl River estuary[J].Marine Environmental Science,2002,21(2):19-22.
[17] Ryu J H,Won J S,Min K D.Waterline extraction from Landsat TM data in a tidal flat:A case study in Gomso Bay,Korea[J].Remote Sensing of Environment,2002,83(3):442-456.
[18] 崔步礼,常学礼,陈雅琳,等.黄河口海岸线遥感动态监测[J].测绘科学,2007,32(3):108-109. Cui B L,Chang X L,Chen Y L,et al.Dynamic monitoring of coastline in the Yellow River estuary by remote sensing[J].Science of Surveying and Mapping,2007,32(3):108-109.
[19] McFeeters S K.The use of the normalized difference water index(NDWI)in the delineation of open water features[J].International Journal of Remote Sensing,1996,17(7):1425-1432.
[20] Vapnik V,Golowich S E,Smola A J.Support vector method for function approximation,regression estimation and signal processing[J].Advances in Neural Information Processing Systems,1996,9:281-287.
[21] Chang C,Lin C.LIBSVM:A library for support vector machines[EB/OL].[2011-03-28].http://www.csie.ntu.edu.tw/~cjlin/papers/libsvm.pdf.
[22] 上海交通大学模式分析与机器智能实验室.LibSVM-2.6程序代码注释[EB/OL].[2011-3-28].http://wenku.baidu.com/view/d32b9a40be1e650e52ea992f.html/. Pattern analysis and machine intelligence laboratory of the Shanghai Jiao Tong University.Notes to the pogram code for LibSVM-2.6[EB/OL].[2011-3-28].http://wenku.baidu.com/view/d32b9a40be1e650e52ea992f.html/.

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