基于遥感时序特征的地表覆被信息提取

doi:10.12118/j.issn.1000–6060.2021.02.16

Abstract

Abstract:

Surface land cover is a special landscape feature modeled by natural and anthropogenic activities, significantly influencing global or local climate, hydrothermal circulation, material transport, and diversity of terrestrial ecosystem communities. Although numerous global or regional land cover datasets have been published, challenges exist in the retrieval of detailed surface cover information, especially on the automatic identification of crop types. Furthermore, the classification accuracy of land-use and land cover maps needs improvement, specifically on crops in the agricultural management community. Using temporal Landsat 8 OLI multispectral images, we analyzed the spectral features of several dominant land cover types from temporal remote sensing images, with a specific emphasis on the unique phenological rhythm of individual plants and investigated the automatic retrieval of land cover types. We organized temporal Landsat 8 OLI surface reflectance data covering Fukang City of Xinjiang, China in the 2016 vegetation growth season. According to the Fukang statistical yearbook, prior knowledge of crop phenology, and the visible texture transition of vegetation in the growing season, we systematically selected the training samples of typical surface covers. We investigated the spectrum, the normalized difference vegetation index, and the enhanced vegetation index temporal curves of 10 typical ground objects, such as agriculture fields of wheat, corn, and cotton, to extract the feature vectors modulated by the growth phase of each crop type. The Euclidean distance was calculated to measure the similarity between unknown surface targets and apriori templates built-up using the above feature vectors and assigned the land cover type according to the K-nearest neighbor rule. As a case study, we applied this approach to the land cover identification of Fukang using the time series of Landsat spectral data in 2018. We validated the retrieval accuracy using 2500 ground samples randomly collected from the land cover map of the investigated area, followed by the manual interpretation of the land cover types using the high-resolution images of 2018 and our field surveys. The results correlate well with the overall accuracy of 97.2% and the Kappa coefficient of 0.9655. Specifically, combined with the field investigation results, the method provides multi-dimensional data for ground object identification and potentially outlines the growth and development progress of different crops, enriches classification information, effectively reduces the phenomenon of foreign matters with the same spectrum in a single time phase, and has potential advantages in improving the identification accuracy of re-plant fields. The time series spectral information captured by this research well reflects the seasonal rhythm and phenological change law of crops in the Fukang region of Xinjiang and provides a novel technical method for the needs of agricultural monitoring.

Key words: time series remote sensing data, phenology of vegetation, spectral characteristics, normalized difference vegetation index, enhanced vegetation index, surface cover mapping

TIAN Yanjun,SHI Ying,SHUAI Yanmin,YANG Jian,SHAO Congying,FAN Lianlian,MA Honghong. Land cover information retrieval from temporal features based remote sensing images[J].Arid Land Geography, 2021, 44(2): 450-459.

Figures/Tables 8

Fig. 1

Fig. 2

Fig. 3

Tab. 1

Fig. 4

Fig. 5

Fig. 6

Tab. 2

References 19

[1]	宫鹏, 张伟, 俞乐, 等. 全球地表覆盖制图研究新范式[J]. 遥感学报, 2016,20(5):1002-1016.
	[ Gong Peng, Zhang Wei, Yu Le, et al. New research paradigm for global land cover mapping[J]. Journal of Remote Sensing, 2016,20(5):1002-1016. ]
[2]	Yu L, Wang J, Clinton N, et al. FROM-GC: 30 m global cropland extent derived through multisource data integration[J]. International Journal of Digital Earth, 2013,6(6):521-533.
[3]	陈军, 陈晋, 宫鹏, 等. 全球地表覆盖高分辨率遥感制图[J]. 地理信息世界, 2011,9(2):12-14.
	[ Chen Jun, Chen Jin, Gong Peng, et al. High resolution remote sensing mapping for global land cover[J]. Geomatics World, 2011,9(2):12-14. ]
[4]	高瑜莲, 柳锦宝, 柳维扬, 等. 近14 a新疆南疆绿洲地区地表蒸散与干旱的时空变化特征研究[J]. 干旱区地理, 2019,42(4):830-837.
	[ Gao Yulian, Liu Jinbao, Liu Weiyang, et al. Spatio-temporal variation characteristics of surface evapotranspiration and drought at the oasis area of the southern Xinjiang in recent 14 years[J]. Arid Land Geography, 2019,42(4):830-837. ]
[5]	王文静, 张霞, 赵银娣, 等. 综合多特征的Landsat 8时序遥感图像棉花分类方法[J]. 遥感学报, 2017,21(1):115-124.
	[ Wang Wenjing, Zhang Xia, Zhao Yindi, et al. Cotton extraction method of integrated multi-features based on multi-temporal Landsat 8 images[J]. Journal of Remote Sensing, 2017,21(1):115-124. ]
[6]	Shuai Y M, Schaaf C, Zhang X Y, et al. Daily MODIS 500 m reflectance anisotropy direct broadcast (DB) products for monitoring vegetation phenology dynamics[J]. International Journal of Remote Sensing, 2013,34(16):5997-6016.
[7]	白燕英, 高聚林, 张宝林. 基于Landsat 8影像时间序列NDVI的作物种植结构提取[J]. 干旱区地理, 2019,42(4):893-901.
	[ Bai Yanying, Gao Julin, Zhang Baolin. Extraction of crop planting structure based on time-series NDVI of Landsat 8 images[J]. Arid Land Geography, 2019,42(4):893-901. ]
[8]	刘吉凯, 钟仕全, 梁文海. 基于多时相Landsat 8 OLI影像的作物种植结构提取[J]. 遥感技术与应用, 2015,30(4):775-783.
	[ Liu Jikai, Zhong Shiquan, Liang Wenhai. Extraction on crops planting structure based on multi-temporal Landsat 8 OLI images[J]. Remote Sensing Technology and Application, 2015,30(4):775-783. ]
[9]	熊元康, 张清凌. 基于NDVI时间序列影像的天山北坡经济带农业种植结构提取[J]. 干旱区地理, 2019,42(5):1105-1114.
	[ Xiong Yuankang, Zhang Qingling. Cropping structure extraction with NDVI time-series images in the northern Tianshan economic belt[J]. Arid Land Geography, 2019,42(5):1105-1114. ]
[10]	胡勇, 刘良云, Caccetta Peter, 等. 光谱特征扩展的时间序列Landsat数据地表覆盖分类[J]. 遥感学报, 2015,19(4):648-656.
	[ Hu Yong, Liu Liangyun, Caccetta Peter, et al. Extraction for land cover based on time series Landsat data of spectral characteristics[J]. Journal of Remote Sensing, 2015,19(4):648-656. ]
[11]	王颖洁, 刘良云, 王志慧. 基于时序Landsat数据的三江平原植被地表类型变化遥感探测研究[J]. 遥感技术与应用, 2015,30(5):959-968.
	[ Wang Yingjie, Liu Liangyun, Wang Zhihui. Land cover mapping based on Landsat time-series stacks in Sanjiang Plain[J]. Remote Sensing Technology and Application, 2015,30(5):959-968. ]
[12]	贺可, 吴世新, 杨怡, 等. 近40 a新疆土地利用及其绿洲动态变化[J]. 干旱区地理, 2018,41(6):1333-1340.
	[ He Ke, Wu Shixin, Yang Yi, et al. Dynamic changes of land use and oasis in Xinjiang in the last 40 years[J]. Arid Land Geography, 2018,41(6):1333-1340. ]
[13]	王一航, 夏沛, 刘志锋, 等. 中国绿洲城市土地利用/覆盖变化研究进展[J]. 干旱区地理, 2019,42(2):341-353.
	[ Wang Yihang, Xia Pei, Liu Zhifeng, et al. Research progress of urban land use/cover change in the oasis cities of China[J]. Arid Land Geography, 2019,42(2):341-353. ]
[14]	汪小钦, 邱鹏勋, 李娅丽, 等. 基于时序Landsat遥感数据的新疆开孔河流域农作物类型识别[J]. 农业工程学报, 2019,35(16):180-188.
	[ Wang Xiaoqin, Qiu Pengxun, Li Yali, et al. Crop identification in Kaikong River Basin of Xinjiang based on time series Landsat remote sensing images[J]. Transactions of the Chinese Society of Agricultural Engineering, 2019,35(16):180-188. ]
[15]	Roy D P, Wulder M A, Loveland T R, et al. Landsat 8: Science and product vision for terrestrial global change research[J]. Remote Sensing of Environment, 2014,145:154-172.
[16]	Masek J G, Vermote E F, Saleouset N E, et al. A Landsat surface reflectance dataset for north America, 1990—2000[J]. Geoscience and Remote Sensing Letters, 2006,3(1):68-72.
[17]	刘焕军, 康苒, Susan Ustin, 等. 基于时间序列高光谱遥感影像的田块尺度作物产量预测[J]. 光谱学与光谱分析, 2016,36(8):2585-2589.
	[ Liu Huanjun, Kang Ran, Susan Ustin, et al. Study on the prediction of cotton yield within field scale with time series hyperspectral imagery[J]. Spectroscopy and Spectral Analysis, 2016,36(8):2585-2589. ]
[18]	杨存建, 周成虎. TM影像的居民地信息提取方法研究[J]. 遥感学报, 2000(2):146-150, 166.
	[ Yang Cunjian, Zhou Chenghu. Extracting residential on the TM imagery[J]. Journal of Remote Sensing, 2000(2):146-150, 166. ]
[19]	白燕英, 高聚林, 张宝林. 基于NDVI与EVI的作物长势监测研究[J]. 农业机械学报, 2019,50(9):153-161.
	[ Bai Yanying, Gao Julin, Zhang Baolin. Monitoring of crops growth based on NDVI and EVI[J]. Transactions of the Chinese Society for Agricultural Machinery, 2019,50(9):153-161. ]

农作物生育期	播种—分蘖	分蘖—返青	返青—拔节	拔节—抽穗	抽穗—成熟
小麦	下/9—上/11	上/11—下/3	下/3—中/4	中/4—中/5	中/5—下/6
农作物生育期	播种—出苗	出苗—拔节	拔节—抽穗	抽穗—乳熟	乳熟—成熟
玉米	下/4—中/5	中/5—下/6	下/6—下/7	下/7—中/8	中/8—中/9
农作物生育期	播种—出苗	出苗—现蕾	现蕾—开花	开花—吐絮	吐絮以后
棉花	下/4—中/5	中/5—中/6	中/6—下/7	下/7—下/9	下/9—上/11
农作物生育期	播种—分蘖	分蘖—拔节	拔节—抽穗	抽穗—灌浆	灌浆—成熟
水稻	下/4—中/5	中/5—下/6	下/6—上/8	上/8—上/9	上/9—下/10
农作物生育期	播种—出苗	出苗—现蕾	现蕾—开花	开花—成熟
油葵	下/4—中/5	中/5—上/6	上/6—下/7	下/7—下/8

分类结果地表真实值	小麦	油葵	玉米	水稻	葡萄	棉花	裸土	草地	居民地	复播	总数	用户精度/%
小麦	170	0	0	0	0	0	0	0	0	0	170	100.00
油葵	0	298	7	0	1	0	0	0	0	0	306	97.39
玉米	0	9	660	4	4	1	0	0	0	0	678	97.35
水稻	0	0	4	39	0	0	0	0	0	0	43	90.70
葡萄	0	0	3	1	175	2	0	0	0	0	181	96.69
棉花	0	0	2	0	2	45	0	0	0	0	49	91.84
裸土	0	0	0	0	0	0	265	7	3	0	275	96.36
草地	0	0	0	0	0	0	7	677	2	0	686	98.69
居民地	0	0	0	0	0	0	5	5	93	0	103	90.29
复播	1	0	0	0	0	0	0	0	0	8	9	88.89
总数	171	307	676	44	182	48	277	689	98	8	总体精度=97.2% Kappa系数=0.9655
生产者精度/%	99.41	97.07	97.63	88.64	96.15	93.75	95.67	98.26	94.90	100	总体精度=97.2% Kappa系数=0.9655

Land cover information retrieval from temporal features based remote sensing images

RichHTML

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 8

References 19

Related Articles 8

Metrics

Comments

Recommended 0

[1]	HE Junqi,WEI Yan,GAO Wande,CHEN Yunfei,MA Yandong,LIU Xiuhua. Temporal and spatial variation of vegetation NDVI and its response to climatic factors in the southeastern margin of Mu Us Sandy Land [J]. Arid Land Geography, 2022, 45(5): 1523-1533.
[2]	DAI Yunhao,GUAN Yao,ZHANG Qinkai,SUN Junjie,HE Xinghong. Remote sensing monitoring and temporal and spatial characteristics of soil salinization in Aral Reclamation Area [J]. Arid Land Geography, 2022, 45(4): 1176-1185.
[3]	CHENG Danni,WANG Yingqi,CHENG Yongxiang,HUANG Jingfeng. Vegetation-water vapor-land surface temperature correlation analysis of typical deserts and oases in Xinjiang [J]. Arid Land Geography, 2022, 45(2): 456-466.
[4]	ZHU Shuzhen,HUANG Farong,LI Lanhai. Drought characteristics and its risk assessment across Pakistan [J]. Arid Land Geography, 2021, 44(4): 1058-1069.
[5]	LI Yupeng,CHEN Yaning,YE Zhaoxia,WANG Fei,SUN Fan,QIN Jingxiu. Ecological responses of ecological water conveyance in the lower reaches of Tarim River for 20 years [J]. Arid Land Geography, 2021, 44(3): 700-707.
[6]	WANG Xin-jun, ZHAO Cheng-yi, YANG Rui-hong, LI Jun. Landscape pattern characteristics of desertification evolution in southern Gurbantunggut Desert [J]. , 2015, 38(6): 1213-1225.
[7]	HE Jian-cun, BAI Yun-gang, ZHANG Yan-jun. Soil drought characteristics in Xinjiang with remote sensing data [J]. , 2015, 38(4): 735-742.
[8]	ZHOU Xiao-li，HU Lie-qun，MA Li-yun，HU Yi-pin. Storm cloud phase in the Tianshan Mountains areas based on FY3A data [J]. , 2014, 37(4): 667-675.