高分一号卫星WFV影像全国陆地镶嵌与制图技术研究

doi:10.6046/gtzyyg.2017.04.29

摘要
参考文献
相关文章
Metrics

全文: PDF(8698 KB)

HTML
输出: BibTeX | EndNote (RIS)

摘要高分一号(GF-1)卫星是我国高空间分辨率对地观测系统重大专项中的首颗卫星,目前已正常运行4 a多,为全国中、高空间分辨率影像镶嵌提供了丰富的数据源。针对GF-1多光谱宽幅覆盖(wide field of view,WFV)影像特点,制定了影像处理的技术流程,主要包括数据选取、几何纠正、匀色镶嵌和制图4项关键技术,重点解决大幅宽影像高精度几何定位问题; 在选取高质量数据基础上,自动采集控制点,控制点均方根误差(root mean square error,RMSE)不大于1个像元,平均每景影像中控制点数量为54个; 应用有理函数模型(rational function model,RFM)对影像进行正射纠正,然后进行色调调整和镶嵌处理,制作全国1:500万比例尺陆地卫星影像专题地图。镶嵌结果具有空间精度高、地物色彩丰富和时效性强等特点。所采用的技术流程和方法可为高分系列卫星全国镶嵌制图提供参考,同时也将促进国产高分卫星在全国重大资源环境调查中的应用推广。

	服务

	把本文推荐给朋友
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	薛庆
	吴蔚
	李名松
	董双发
	章新益
	石海港

关键词 ：高分一号, 矿山遥感监测, 数据处理, 信息提取

Abstract：GF-1 is the first satellite in the major projects of high resolution observation system in China. It has provided abundant data for high and moderate spatial resolution image mosaicking for more than four years since its launching. The process of image mosaicking was based on the characteristics of the wide field of view (WFV)images of GF-1,including four key techniques i.e., data selection, geometric rectification, color adjustment, image mosaicking and mapping. The high precision geometric positioning of wide image is the key technology. After high quality data selection, ground control points (GCPs) were collected automatically. The root mean square error(RMSE)of each image should be less than 1 pixel with the average number of GCPs being 54. Then rational function model(RFM)was applied to the images for ortho-rectification. The 1: 5 000 000 national land image map was completed after color adjustment and mosaicking. This map has high spatial accuracy, colored pixels and temporal resolution. The method proposed in this paper could provide an important reference for the series of GF satellites image mosaicking and mapping, and would promote the domestic satellites to play a greater role in investigation of major resources and environment in China.

Key words： GF-1 mine remote sensing monitoring data processing information extraction

收稿日期: 2016-04-27 出版日期: 2017-12-04

TP751.1

基金资助:国家重点研发计划全球变化及应对专项课题项目“大尺度全球变化数据产品快速生成方法”(编号: 2016YFA0600302)、海南省重大科技计划项目“海南省遥感大数据服务平台建设与应用示范”(编号: ZDKJ2016021)和海南省重大科技计划项目“新型海洋信息感知关键技术及设备研发”(编号: ZDKJ2016015)共同资助

通讯作者: 何国金(1968-),男,研究员,博士生导师,主要从事遥感信息挖掘与智能处理等研究。Email: hegj@radi.ac.cn。

作者简介: 江威(1991-),男,博士研究生,主要研究方向为遥感图像处理与夜光遥感数据应用。Email: jiangweifz@163.com。

引用本文:

江威, 何国金, 刘慧婵, 龙腾飞, 王威, 郑守住, 马肖肖. 高分一号卫星WFV影像全国陆地镶嵌与制图技术研究[J]. 国土资源遥感, 2017, 29(4): 190-196.
JINAG Wei, HE Guojin, LIU Huichan, LONG Tengfei, WANG Wei, ZHENG Shouzhu, MA Xiaoxiao. Research on China’s land image mosaicking and mapping technology based on GF-1 satellite WFV data. REMOTE SENSING FOR LAND & RESOURCES, 2017, 29(4): 190-196.

链接本文:

https://www.gtzyyg.com/CN/10.6046/gtzyyg.2017.04.29 或 https://www.gtzyyg.com/CN/Y2017/V29/I4/190

[1]　何国金,王力哲,马艳,等.对地观测大数据处理:挑战与思考[J].科学通报,2014,60(5/6):470-478.
He G J,Wang L Z,Ma Y,et al.Processing of earth observation big data:Challenges and countermeasures[J].Chinese Science Bulletin,2015,60(5/6):470-478.
[2]　郭华东,傅文学,李新武,等.全球变化科学卫星概念研究[J].中国科学:地球科学,2014,44(1):49-60.
Guo H D,Fu W X,Li X W,et al.Research on global change scientific satellites[J].Science China Earth Sciences,2014,57(2):204-215.
[3]　RTU产品数据服务计划[EB/OL].(2015-03-10)[2016-06-16].http://ids.ceode.ac.cn/rtu/index.aspx.
The plan of RTU product data service[EB/OL].(2015-03-10) [2016-06-16].http://ids.ceode.ac.cn/rtu/index.aspx.
[4]　汪爱华,迟耀斌,王智勇,等.北京1号小卫星多光谱影像全国镶嵌技术与制图研究[J].遥感学报,2009,13(1):83-90.
Wang A H,Chi Y B,Wang Z Y,et al.Study on mosaic technology and mapping of China based on the multispectral images of Beijing-1 small satellite[J].Journal of Remote Sensing,2009,13(1):83-90.
[5]　卫征,陈正超,张兵,等.CBERS-1影像全国数字镶嵌与制图[J].中国图象图形学报,2006,11(6):787-791.
Wei Z,Chen Z C,Zhang B,et al.CBERS-1 digital images mosaic and mapping of China[J].Journal of Image and Graphics,2006,11(6):787-791.
[6]　程乾,陈金凤.基于高分1号杭州湾南岸滨海陆地土地覆盖信息提取方法研究[J].自然资源学报,2015,30(2):350-360.
Cheng Q,Chen J F.Research on the extraction method of landcover information in southern coastal land of Hangzhou Bay based on GF-1 Image[J].Journal of Natural Resources,2015,30(2):350-360.
[7]　王中挺,辛金元,贾松林,等.利用暗目标法从高分一号卫星16 m相机数据反演气溶胶光学厚度[J].遥感学报,2015,19(3):530-538.
Wang Z T,Xin J Y,Jia S L,et al.Retrieval of AOD from GF-1 16 m camera via DDV algorithm[J].Journal of Remote Sensing,2015,19(3):530-538.
[8]　朱利,李云梅,赵少华,等.基于GF-1号卫星WFV数据的太湖水质遥感监测[J].国土资源遥感,2015,27(1):113-120.doi:10.6046/gtzyyg.2015.01.18.
Zhu L,Li Y M,Zhao S H,et al.Remote sensing monitoring of Taihu Lake water quality by using GF-1 satellite WFV data[J].Remote Sensing for Land and Resources,2015,27(1):113-120.doi:10.6046/gtzyyg.2015.01.18.
[9]　刘国栋,邬明权,牛铮,等.基于GF-1卫星数据的农作物种植面积遥感抽样调查方法[J].农业工程学报,2015,31(5):160-166.
Liu G D,Wu M Q,Niu Z,et al.Investigation method for crop area using remote sensing sampling based on GF-1 satellite data[J].Transactions of the Chinese Society of Agricultural Engineering,2015,31(5):160-166.
[10] Wang L,Yang R R,Tian Q J,et al.Comparative analysis of GF-1 WFV,ZY-3 MUX,and HJ-1 CCD sensor data for grassland monitoring applications[J].Remote Sensing,2015,7(2):2089-2108.
[11] 赵少华,王桥,杨一鹏,等.高分一号卫星环境遥感监测应用示范研究[J].卫星应用,2015(3):37-40.
Zhao S H,Wang Q,Yang Y P,et al.The demonstration research of GF-1 satellite data monitoring environment application[J].Satellite Application,2015(3):37-40.
[12] 高分一号[EB/OL].(2014-12-16)[2015-10-15].http://www.cresda.com/n16/n1130/n188475/188494.html.
Gaofenyihao[EB/OL].(2014-12-16)[2015-10-15].http://www.cresda.com/n16/n1130/n188475/188494.html.
[13] 黄世存,李杏朝,芦祎霖,等.基于CBERS-02星的全国影像镶嵌图制作[J].国土资源遥感,2008,20(3):42-44.doi:10.6046/gtzyyg.2008.03.10.
Huang S C,Li X C,Lu Y L,et al.The mosaic and mapping of China digital images based on CBERS-02 data[J].Remote Sensing for Land and Resources,2008,20(3):42-44.doi:10.6046/gtzyyg.2008.03.10.
[14] Anuta P E.Spatial registration of multispectral and multitemporal digital imagery using fast Fourier transform techniques[J].IEEE Transactions on Geoscience Electronics,1970,8(4):353-368.
[15] Reddy B S,Chatterji B N.An FFT-based technique for translation,rotation,and scale-invariant image registration[J].IEEE Transactions on Image Processing,1996,5(8):1266-1271.
[16] 孙家抦.遥感原理与应用[M].3版.武汉:武汉大学出版社,2013:105-116.
Sun J B.Principles and Applications of Remote Sensing[M].3rd ed.Wuhan:Wuhan University Press,2013:105-116.
[17] Long T F,Jiao W L,He G J.Nested regression based optimal selection(NRBOS) of rational polynomial coefficients[J].Photogrammetric Engineering and Remote Sensing,2014,80(3):261-269.

[1]	吕品, 熊丽媛, 徐争强, 周学铖. 基于FME的矿山遥感监测矢量数据图属一致性检查方法[J]. 自然资源遥感, 2022, 34(1): 293-298.
[2]	魏英娟, 刘欢. 北衙金矿床遥感矿化蚀变信息提取及找矿预测[J]. 自然资源遥感, 2021, 33(3): 156-163.
[3]	牟晓莉, 李贺, 黄翀, 刘庆生, 刘高焕. Google Earth Engine在土地覆被遥感信息提取中的研究进展[J]. 国土资源遥感, 2021, 33(2): 1-10.
[4]	陈栋, 姚维岭. 基于ArcPy与定制ArcToolbox的矿山新增图斑自动编号及方法改进[J]. 国土资源遥感, 2021, 33(2): 262-269.
[5]	夏炎, 黄亮, 陈朋弟. 模糊超像素分割算法的无人机影像烟株精细提取[J]. 国土资源遥感, 2021, 33(1): 115-122.
[6]	王琳, 谢洪波, 文广超, 杨运航. 基于Landsat8的含蓝藻湖泊水体信息提取方法研究[J]. 国土资源遥感, 2020, 32(4): 130-136.
[7]	栗旭升, 刘玉锋, 陈冬花, 刘赛赛, 李虎. 结合图像特征的支持向量机高分一号云检测[J]. 国土资源遥感, 2020, 32(3): 55-62.
[8]	刘晰, 郝利娜, 杨显华, 黄洁, 张志, 杨武年. 矿山遥感监测指标快速统计方法研究与实现[J]. 国土资源遥感, 2020, 32(2): 259-265.
[9]	张祝鸿, 王保云, 孙玉梅, 李才东, 孙显辰, 张玲莉. 结合笔画宽度变换与几何特征集的高分一号遥感图像河流提取[J]. 国土资源遥感, 2020, 32(2): 54-62.
[10]	彭继达, 张春桂. 基于高分一号遥感影像的植被覆盖遥感监测——以厦门市为例[J]. 国土资源遥感, 2019, 31(4): 137-142.
[11]	刘畅, 杨康, 程亮, 李满春, 郭紫燕. Landsat8不透水面遥感信息提取方法对比[J]. 国土资源遥感, 2019, 31(3): 148-156.
[12]	尹展, 张利军, 段建良, 张沛. 南方植被区强迫不变植被抑制技术改进与应用[J]. 国土资源遥感, 2019, 31(2): 82-88.
[13]	史园莉, 孙中平, 姜俊, 高乾, 孙浩, 闻瑞红. 环境遥感云服务平台与高性能平台对比分析[J]. 国土资源遥感, 2019, 31(2): 240-245.
[14]	高晨, 徐健, 高丹, 王莉莉, 王野乔. 基于GF-1与实测光谱数据鄱阳湖丰水期总悬浮物浓度反演[J]. 国土资源遥感, 2019, 31(1): 101-109.
[15]	王月如, 韩鹏鹏, 关舒婧, 韩宇, 易琳, 周廷刚, 陈劲松. 基于Landsat8 OLI数据的富贵竹种植区域信息提取[J]. 国土资源遥感, 2019, 31(1): 133-140.

Viewed

Full text

Abstract

Cited

Shared

Discussed