联合星载光学和SAR影像的漳江口红树林与互花米草遥感监测

doi:10.11978/2019063

摘要/Abstract

摘要：

文章以福建省漳江口国家级红树林自然保护区为研究区, 提出了一种联合星载光学和合成孔径雷达(SAR)影像的红树林与互花米草分布的自动提取算法, 提取研究区内红树林和互花米草的空间分布。本研究选择2016年、2017年和2018年各一景低潮时的Sentinel-2 A光学影像数据, 获取植被和其他地物的光谱和纹理信息。算法首先基于归一化植被指数、增强型植被指数、地表水分指数以及数字高程模型的相关规则计算红树林和互花米草的潜在分布区; 通过随机森林分类算法区分红树林和互花米草, 2016年、2017年和2018年影像的分类总体精度和Kappa系数分别为98.53%和0.980、96.52%和0.952、98.71%和0.978, 分类效果良好; 使用当年所有Sentinel-1 A/B的SAR影像获得研究区的常年海水分布范围, 使用与海水交界的判据, 实现红树林、互花米草提取范围的优化。研究表明, 研究区2016年、2017年和2018年红树林总面积分别为56.85hm²、59.88hm²和58.61hm², 互花米草总面积分别为109.23hm²、124.00hm²和142.39hm², 与前人的研究成果在红树林和互花米草的空间分布和面积量级上有较好的一致性。

关键词: 红树林, 互花米草, 遥感, 分层分类, 随机森林分类, 漳江口

Abstract:

Mangroves are an important type of coastal wetlands with ecological, environmental, economic, and cultural values. Spartina alterniflora is an invasive alien plant, threatening mangroves in China. The competition between Spartina alterniflora and mangroves is an important ecological issue along the southeast coast of China. Accurate monitoring of Spartina alterniflora and mangroves with remote sensing is of great significance for scientific protection of mangrove ecosystems. We propose a new method to monitor Spartina alterniflora and mangroves, integrating Sentinel-1 SAR and Sentinel-2 optical imagery. The Yunxiao National Nature Reserve of Mangroves, located in Zhangjiang Estuary, Fujian, China, is chosen as the study area. We select one Sentinel-2A image at low tide in 2016, 2017 and 2018 to obtain the spectral and texture information of vegetation and other objects. The new method comprises of three steps: 1) use rules related to NDVI, EVI, LSWI, and DEM to get the potential masks of Spartina alterniflora and mangroves; 2) use random forest classification method to distinguish Spartina alterniflora and mangroves further; and 3) use all Sentinel-1 A/B images in that year to get the estuarine yearlong seawater body, and use the criterion interaction with sea water to refine the detected Spartina alterniflora and mangroves. The random forest classifier is found suitable for mapping wetlands with overall accuracy of 98.53%, 96.52% and 98.71%, and Kappa coefficients of 0.980, 0.952 and 0.978 in 2016, 2017 and 2018, respectively. The total areas of the detected Spartina alterniflora and mangroves in the study region are 109.23 and 56.85 hm ²in 2016, 124.00 and 59.88 hm² in 2017, and 142.39 and 58.61 hm² in 2018, respectively, consistent with previous research results in terms of spatial distribution and magnitude of the area.

Key words: mangroves, Spartina alterniflora, remote sensing, hierarchical classification, random forest classification, Zhangjiang Estuary

中图分类号:

P735.52

董迪, 曾纪胜, 魏征, 严金辉. 联合星载光学和SAR影像的漳江口红树林与互花米草遥感监测[J]. 热带海洋学报, 2020, 39(2): 107-117.

Di DONG, Jisheng ZENG, Zheng WEI, Jinhui YAN. Integrating spaceborne optical and SAR imagery for monitoring mangroves and Spartina alterniflora in Zhangjiang Estuary[J]. Journal of Tropical Oceanography, 2020, 39(2): 107-117.

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类别	红树林	互花米草	水	光滩	其他植被
2016年与2017年	40 (10.13)	38 (2.04)	12 (21.25)	22 (5.58)	17 (0.47)
2018年	40 (10.13)	55 (2.70)	12 (21.25)	22 (5.58)	22 (0.66)

年度	类别	红树林	互花米草	光滩	水	其他植被	制图精度/%	用户精度/%
2016年	红树林	418	0	0	0	0	100.00	100.00
	互花米草	0	99	3	0	0	97.06	100.00
	光滩	0	0	422	2	8	97.69	98.60
	水	0	0	0	318	1	99.69	98.76
	其他植被	0	0	3	2	17	77.27	65.39
2017年	红树林	418	0	0	0	0	99.76	99.76
	互花米草	0	90	1	9	2	94.74	94.74
	光滩	0	0	402	19	6	99.26	99.26
	水	0	5	0	319	0	91.93	91.93
	其他植被	1	0	2	0	19	70.37	70.37
2018年	红树林	486	0	0	0	1	99.80	100.00
	互花米草	0	76	5	0	0	93.83	98.70
	光滩	0	0	18	0	0	100.00	60.00
	水	0	0	0	628	2	99.68	100.00
	其他植被	0	1	7	0	18	69.23	85.71

类别	2014年	2015年	2016年	2017年	2018年
红树林	59.91 (李屹等, 2017)	62.19 (Chen et al, 2017)	60 (陈远丽等, 2019); 56.85 (本算法)	59.88 (本算法)	58.61 (本算法)
互花米草	—	116.11 (Liu et al, 2017)	117 (陈远丽等, 2019); 109.23 (本算法)	124.00 (本算法)	142.39 (本算法)

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