基于高分辨率遥感影像的湿地互花米草-芦苇混合交错带提取方法

doi:10.3724/SP.J.1047.2017.01375

地球信息科学学报 ›› 2017, Vol. 19 ›› Issue (10): 1375-1381.doi: 10.3724/SP.J.1047.2017.01375

基于高分辨率遥感影像的湿地互花米草-芦苇混合交错带提取方法

姚红岩¹(), 刘浦东^1,^2,³, 施润和^1,^2,^3,^4,^*(), 张超^1,^2,^3,⁴

1. 华东师范大学地理科学学院,上海 200241
2. 华东师范大学地理信息科学教育部重点实验室,上海 200241
3. 华东师范大学环境遥感与数据同化联合实验室,上海 200241
4. 华东师范大学美国科罗拉多州立大学中美新能源与环境联合研究院, 上海 200062

收稿日期:2017-03-30 修回日期:2017-08-30 出版日期:2017-10-20 发布日期:2017-10-20
作者简介:
作者简介：姚红岩（1995-）,女,吉林辽源人,本科生,主要从事植被遥感方面的研究。E-mail: yaohongyan0327@126.com
基金资助:
国家自然科学基金项目（31500392）;国家高分辨率对地观测专项课题（10-Y30B11-9001-14/16）;国家重点研发计划项目课题（2016YFC1302602）;上海市科委重大专项课题（15dz1207805）;上海市卫计委重点学科建设项目（15GWZK0201）

Extracting the Transitional Zone of Spartina alterniflora and Phragmites australis in the Wetland Using High-resolution Remotely Sensed Images

YAO Hongyan¹(), LIU Pudong^1,^2,³, SHI Runhe^1,^2,^3,^4,^*(), ZHANG Chao^1,^2,^3,⁴

1. School of Geographic Sciences, East China Normal University, Shanghai 200241, China
2. Key Laboratory of Geographical Information Science, Ministry of Education, East China Normal University, Shanghai 200241, China
3. Joint Laboratory for Environmental Remote Sensing and Data Assimilation, East China Normal University, Shanghai, 200241 China
4. Joint Research Institute for New Energy and the Environment, East China Normal University and Colorado State University, Shanghai 200062, China

Received:2017-03-30 Revised:2017-08-30 Online:2017-10-20 Published:2017-10-20

摘要/Abstract

摘要：

互花米草是中国东部河口滩涂湿地主要入侵物种之一,其与本地物种芦苇竞争生长,形成了大范围的混合交错带。该交错带是研究湿地生态系统动态变化的重要信息,但因2种物种光谱的相似性及其在交错带的组成复杂性,使利用遥感技术提取交错带难度较大。因此,本文提出了一种将二者生长物候差异与其光谱特征相结合,考虑二者海陆位置分布差异,运用实测剖面观测数据确定光谱指标和阈值的综合提取方法。运用高分一号多光谱遥感数据,通过分析不同时相互花米草与芦苇冠层光谱差异,确定用来提取混合交错带的高分遥感影像,实现了研究区互花米草-芦苇混合交错带的提取。结果表明：不同时相宜选用不同的提取指标,本研究中在春季选择了近红外波段反射率,而秋季则选择了红波段反射率;2个时相的混合交错带范围存在明显差异,客观反映了互花米草与芦苇在不同季节的竞争状况。

关键词: 混合交错带, 互花米草, 芦苇, 光谱特征, 高分一号

Abstract:

Spartina alterniflora is one of the major invasive species putting a high pressure to the native Phragmites australis in the coastal wetland in Chongming Island, Shanghai. Both species grow up together and result in extensive transitional zones. Spartina alterniflora and Phragmites australis have differences in physiology. The former prefers to live in a high-salt environment and it distributes closer to the sea. In the transitional zones, the two species mix in different proportion along the direction from the sea to the land and grow competitively with each other. Their growth in the transitional zones reflects the intensity of competition. Moreover, the change of the location of transitional zones reflects the dynamic process of the invasion of Spartina alterniflora. Thus, the transitional zone plays a key role in the study of dynamic change of wetland ecosystem. However, it is difficult to extract such information precisely by remote sensing because of the similar spectra of two species and complex composition of the transitional zone. They have similarities in both spectra and physiological and ecological characteristics because both of them are gramineous plants. In addition, the two species in transitional zones mix with different proportions in different regions, so the composition of the transitional zones is complex. There is little related research focusing on the transitional zones so far. This paper presents a comprehensive extraction method. Firstly, we combine different phenology with spectral characteristics to narrow the scope of the appropriate indicators down to reduce the workload. Secondly, we also consider location difference of the land and the sea. Analyzing the spectral characteristics along the direction from the sea to the land, it will be more intuitive for the spectral characteristics of vegetation in the transitional zones as well as the relationship between the change of mixing ratios and spectral characteristics. Finally, we determine extracting indicators and threshold by actual measured dataset. Remote sensing is an important measure for monitoring wetland ecosystem. Extracting transitional zone requires high-resolution remotely sensed images because the width of transitional zone in our research is narrow and transitional zone contains many patches which is due to many complex factors such as underwater micro-topography differences. This study selected appropriate multi-spectral remotely sensed data from GF-1 as research object through analyzing the canopy spectral differences between Spartina alterniflora and Phragmites australis in different time. Also, this study extracted transitional zone successfully in the study area which is an intertidal area located in the northeastern part of Chongming Island. The results indicate that different indicators should be used in different time. We select near-infrared band reflectance for spring and red band reflectance for autumn The near-infrared band reflectance of vegetation in transitional zone is lower than the other two pure species regions in spring while the red band reflectance is higher than the other two pure species regions in autumn. The scale of transitional zone has obvious difference in the two growing stages, the width of transitional zone in autumn is narrower than that in spring and the location moves towards the direction of Phragmites australis regions. The difference reflects the competitive situation in different seasons, objectively. Competitive edge of Spartina alterniflora is more evident in autumn.

Key words: transitional zone, Spartina alterniflora Loisel, Phragmites australis, spectral characteristic, GF-1

姚红岩, 刘浦东, 施润和, 张超. 基于高分辨率遥感影像的湿地互花米草-芦苇混合交错带提取方法[J]. 地球信息科学学报, 2017, 19(10): 1375-1381.DOI:10.3724/SP.J.1047.2017.01375

YAO Hongyan,LIU Pudong,SHI Runhe,ZHANG Chao. Extracting the Transitional Zone of Spartina alterniflora and Phragmites australis in the Wetland Using High-resolution Remotely Sensed Images[J]. Journal of Geo-information Science, 2017, 19(10): 1375-1381.DOI:10.3724/SP.J.1047.2017.01375

图/表 6

图1

图2

图3

图4

表1

图5

参考文献 18

[1]	Costanza R, d’Arge R, de Groot R, et al. The value of the world’s ecosystem services and natural capital[J]. Nature, 1997,387:253-260. doi: 10.1038/387253a0
[2]	陈中义. 互花米草入侵国际重要湿地崇明东滩的生态后果[D].上海:复旦大学,2004.
	[ Chen Z Y.Ecological impacts of the introduced Spartina alterniflora invasions in the coastal ecosystems of Chongming Dongtan, the Yangtze River estuary[D]. Shanghai: Fudan University, 2004. ]
[3]	李加林,杨晓平,童亿勤等.互花米草入侵对潮滩生态系统服务功能的影响及其管理[J].海洋通报,2005,24(5):33-38. doi: 10.3969/j.issn.1001-6392.2005.05.006
	[ Li J L, Yang X P, Tong Y Q, et al.Influences of Spartina alterniflora invasion on ecosystem services of coastal wetland and its countermeasures[J]. Marine Science Bulletin, 2005,24(5):33-38. ] doi: 10.3969/j.issn.1001-6392.2005.05.006
[4]	王卿. 长江口盐沼植物群落分布动态及互花米草入侵的影响[D].上海:复旦大学,2007.
	[ Wang Q.The dynamic distribution of plant community of the salt marshes in the Yangtze river estuary as influenced by invasions Spartina alterniflora[D]. Shanghai: Fudan University, 2007. ]
[5]	Jiang L F, Luo Y Q, Chen J K, et al.Ecophysiological characteristics of invasive Spartina alterniflora and native species in salt marshes of Yangtze River estuary, China[J]. Estuarine, Coastal and Shelf Science, 2009,81(1):74-82. doi: 10.1016/j.ecss.2008.09.018
[6]	Tyler A C, Lambrinos J G, Grosholz E D.Nitrogen inputs promote the spread of an invasive marsh grass[J]. Ecological Applications, 2007,17(7):1886-1898. doi: 10.1890/06-0822.1 pmid: 17974329
[7]	Sadro S, Gastil-Buhl M, Melack J.Characterizing patterns of plant distribution in a southern California salt marsh using remotely sensed topographic and hyperspectral data and local tidal fluctuations[J]. Remote Sensing of Environment, 2007,110(2):226-239. doi: 10.1016/j.rse.2007.02.024
[8]	Tuxen K, Schile L, Stralberg D, et al.Mapping changes in tidal wetland vegetation composition and pattern across a salinity gradient using high spatial resolution imagery[J]. Wetlands Ecology and Management, 2011,19(2):141-157. doi: 10.1007/s11273-010-9207-x
[9]	Kumar L, Sinha P.Mapping salt-marsh land-cover vegetation using high-spatial and hyperspectral satellite data to assist wetland inventory[J]. GIScience & Remote Sensing, 2014,51(5):438-497. doi: 10.1080/15481603.2014.947838
[10]	Gilmore M S, Wilson E H, Barrett N, et al.Integrating multi-temporal spectral and structural information to map wetland vegetation in a lower Connecticut River tidal marsh[J]. Remote Sensing of Environment, 2008,112(11):4048-4060. doi: 10.1016/j.rse.2008.05.020
[11]	高占国. 长江口盐沼植被的光谱特征研究[D].上海:华东师范大学,2006.
	[ Gao Z G.A study on the spectral characteristics of salt marsh vegetation in Yangtze estuary[D]. Shanghai: East China Normal University, 2006. ]
[12]	杨立君,马明栋,唐立军.基于TM影像的崇明东滩湿地植被分类研究[J].水土保持研究, 2013,20(1):126-130.
	[ Yang L J, Ma M D, Tang L J. Research on wetland vegetation classification of Chongming Eastern Tidal Flat based on TM images[J]. Research of Soil and Water Conservation, 2013,20(1):126-130. ]
[13]	Ai J Q, Gao W, Gao Z Q, et al.Integrating pan-sharpening and classifier ensemble techniques to map an invasive plant (Spartina alterniflora) in an estuarine wetland using Landsat 8 imagery[J]. Journal of Applied Remote Sensing, 2016,10(2):026001. doi: 10.1117/1.JRS.10.026001
[14]	赵赛帅. 基于环境卫星NDVI时间序列的盐沼植被分类与提取[D].南京:南京大学,2015.
	[ Zhao S S.Salt marsh classification and extraction based on HJ NDVI time series[D]. Nanjing: Nanjing University, 2015. ]
[15]	汪承焕. 环境变异对崇明东滩优势盐沼植物生长、分布与种间竞争的影响[D].上海:复旦大学,2009.
	[ Wang C H.Effects of environmental variation on growth, distribution of marsh plants and their interspecific interactions at Chongming Dongtan[D]. Shanghai: Fudan University, 2009. ]
[16]	肖燕,汤俊兵,安树青.芦苇、互花米草的生长和繁殖对盐分胁迫的响应[J].生态学杂志,2011(2):267-272.
	[ Xiao Y, Tang J B, An S Q.Responses of growth and sexual reproduction of Phragmites australis and Spartina alterniflora to salinity stress[J]. Chinese Journal of Ecology, 2011,2:267-272. ]
[17]	赵聪蛟,邓自发,周长芳等.氮水平和竞争对互花米草与芦苇叶特征的影响[J].植物生态学报, 2008,2:392-401. ]
	[ Zhao C J, Deng Z F, Zhou C F, et al. Effects of nitrogen availability and competition on leaf characteristics of Spartina alterniflora and Phragmites australis[J]. Journal of Plant Ecology, 2008,2:392-401. ]
[18]	袁月,李德志,王开运.芦苇和互花米草入侵性研究进展[J].湿地科学,2014(4):533-538.
	[ Yuan Y, Li D Z, Wang K Y.Research progress in mutual invasion of Phragmites australis and Spartina alterniflora communities[J]. Wetland Science, 2014,4:533-538. ]

季节	光谱指标	纯互花米草	纯芦苇	混合交错带
春季	ρ_NIR	0.180-0.240	0.211-0.316	0.135-0.180
秋季	ρ_RED	0.066-0.092	0.087-0.101	0.101-0.125

基于高分辨率遥感影像的湿地互花米草-芦苇混合交错带提取方法

Extracting the Transitional Zone of Spartina alterniflora and Phragmites australis in the Wetland Using High-resolution Remotely Sensed Images

RichHTML

PDF (PC)

赞

可视化

被引次数

摘要/Abstract

引用本文

使用本文

图/表 6

参考文献 18

相关文章 12

Metrics

本文评价

推荐阅读 0

[1]	巫磊, 吴文挺. GEE平台下结合滤波算法和植被物候特征的互花米草遥感提取最优时间窗口确定[J]. 地球信息科学学报, 2023, 25(3): 606-624.
[2]	邢晓语, 杨秀春, 徐斌, 金云翔, 郭剑, 陈昂, 杨东, 王平, 朱立博. 基于随机森林算法的草原地上生物量遥感估算方法研究[J]. 地球信息科学学报, 2021, 23(7): 1312-1324.
[3]	李俊杰, 陈舒博, 张文, 余长慧, 张志远, 孟令奎. 基于ODC的国产卫星影像存储与应用研究[J]. 地球信息科学学报, 2020, 22(9): 1860-1867.
[4]	周伟, 李浩然, 石佩琪, 谢利娟, 杨晗. 三江源区毒杂草型退化草地植被光谱特征分析[J]. 地球信息科学学报, 2020, 22(8): 1735-1742.
[5]	叶杰, 孟凡晓, 白潍铭, 张斌, 郑金明. “四同”条件下周口城区高分一号遥感影像分类对比研究[J]. 地球信息科学学报, 2020, 22(10): 2088-2097.
[6]	金续, 张显峰, 罗伦, 潘一凡, 阳柯. 公路路面光谱特征分析与沥青路面老化遥感监测方法初探[J]. 地球信息科学学报, 2017, 19(5): 672-681.
[7]	张翠芬, 帅爽, 郝利娜, 刘晰. GF-1影像和OLI影像协同土地利用模糊分类方法研究[J]. 地球信息科学学报, 2017, 19(1): 1-9.
[8]	张璐, 施润和, 徐永明, 李龙, 高炜. 国产遥感传感器大气层外波段平均太阳光谱辐照度计算[J]. 地球信息科学学报, 2014, 16(4): 621-627.
[9]	喻小勇, 邵全琴, 刘纪远, 胡卓玮. 三江源区不同退化程度的高寒草甸光谱特征分析[J]. 地球信息科学学报, 2012, 14(3): 398-404.
[10]	王卷乐, 李锐, 徐永芬, 徐育林, 贾文臣, 邓凤东. 面向数据共享的城镇化信息快速提取技术方法与应用——以江苏盐城为例[J]. 地球信息科学学报, 2010, 12(3): 399-405.
[11]	钟春棋, 曾从盛, 柳铮铮. 基于谱间特征与比值型指数的水体影像识别分析[J]. 地球信息科学学报, 2008, 10(5): 663-669.
[12]	景娟娟, 潘瑜春, 王纪华, 王锦地, 赵春江. 土地利用变更的遥感应用分析[J]. 地球信息科学学报, 2003, 5(2): 94-99.