The construction and verification of a water index in the complex environment based on GF-2 images

doi:10.6046/zrzyyg.2021227

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Abstract

The high spatial resolution of GF-2 images helps to obtain more accurate water distribution information. This study constructed a water index based on GF-2 images and verified it, aiming to solve the problem that the salt and pepper noise is prone to occur when the existing water indices are used to extract information on water bodies in complex environments from high-resolution remote sensing images. Firstly, this study established a comprehensive water index (CWI) by analyzing the spectral information of surface coverings and verified its precision. Secondly, information on water bodies was extracted through image segmentation combined with the CWI, and the extraction precision was verified. Then, to fully utilize the spectral information and the advantages of a classifier, the spectral information on the segmented homogeneous objects and the CWI were combined as the input data of the classifier to extract information on water bodies and verify the extraction precision. Finally, this study verified the applicability of the CWI in both WorldView-2 and GF-1 images. The results are as follows. ① The newly constructed CWI can effectively suppress the impacts of surface coverings, such as shadow, buildings, roads, vegetation, and bare soil, thus significantly improving the extraction precision. ② Extracting information on water bodies through image segmentation combined with the CWI can effectively inhibit the occurrence of the pepper and salt noise. ③ A classifier combined with a water index can effectively improve the information extraction precision of water bodies. ④ The CWI is applicable to both WorldView-2 and GF-1 images. In sum, the CWI can be used to effectively extract information on water bodies and applies to the information extraction and renewal of rivers and lakes and the surveys of the cultivation area of pounds and thereby is a high-precision method for extraction information of water bodies.

Keywords information extraction of water bodies comprehensive water index GF-2 support vector machine random forest

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Corresponding Authors: ZHANG Jun E-mail: 1821851037@qq.com;jzhang13@gzu.edu.cn

Issue Date: 21 September 2022

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	Chunxia WANG
	Jun ZHANG
	Yixu LI
	PHOUMILAY

Cite this article:

Chunxia WANG,Jun ZHANG,Yixu LI, et al. The construction and verification of a water index in the complex environment based on GF-2 images[J]. Remote Sensing for Natural Resources, 2022, 34(3): 50-58.

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https://www.gtzyyg.com/EN/10.6046/zrzyyg.2021227 OR https://www.gtzyyg.com/EN/Y2022/V34/I3/50

Fig.1 Spectral curve of average reflectance of each surface feature

Fig.2 Distribution of water body index of various surface features

模型名称	计算公式^①	来源
归一化差异植被指数	$N D V I = (ρ N I R - ρ R E D) / (ρ R E D + ρ N I R)$	[27]
归一化差异水体指数	$N D W I = (ρ G R E E N - ρ N I R) / (ρ G R E E N + ρ N I R)$	[15]
阴影水体指数	$S W I = ρ B L U E + ρ G R E E N - ρ N I R$	[19]
改进的阴影水体指数	$M S W I = (ρ B L U E - ρ N I R) / ρ N I R$	[6]
增强的阴影水体指数	$E S W I = (ρ B L U E + ρ G R E E N) / (2 ρ N I R)$	[28]

Tab.1 Common used water indexes

Tab.2 Characteristics of the study area

Fig.3 Results of water body extraction in site 1

Tab.3 Results of accuracy assessment in site 1(%)

Fig.4 Results of water body extraction in site 2

Fig.5 Enlarged view in site 2

Tab.4 Results of accuracy assessment in site 2(%)

Tab.5 Water extraction results of different data combinations

Tab.6 Water extraction accuracy evaluation of different data combinations(%)

Fig.6 Result of water body extraction in Site 2

Fig.7 Results of water body extraction in site 3

Tab.7 Results of accuracy assessment in site 3(%)

Fig.8 Results of water body extraction in site 4

Tab.8 Results of accuracy assessment in site 4(%)

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