Progress in construction of remote sensing and geological test field for comprehensive application and resources evaluation in Hami, Xinjiang

doi:10.6046/gtzyyg.2015.02.02

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Abstract The remote sensing geological test field is the most important basic platform for comprehensive application and evaluation of remote sensing and geological resources. The construction of the remote sensing geological test field is aimed at meeting the needs of the geological application for land and resources and satisfying the development requirement of remote sensing geological technology as well as the coordinated development of the remote sensing technology with other techniques. The remote sensing geological test field can improve the quantification level of remote sensing geological survey and avoid the blindness of remote sensing data application and promotion. Under the leadership and support of China Geological Survey, the construction and research work of the remote sensing geological test field was carried out. Now, the remote sensing geological test field has been basically established, which has the preliminary capability of providing application services. In this paper, the authors mainly describe the structure, function and performance of the remote sensing geological test field as well as the service mode and service capability that the remote sensing geological test field could provide, so as to make the people understand the development of the remote sensing geological test field and then carry out the research work on the remote sensing technical methodology and basic theory based on the remote sensing geological test field in the hope that the construction and development of the remote sensing geological test field can be accelerated.

Keywords built-up area new Beichuan neutrosphic set mean shift high spatial resolution

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Issue Date: 02 March 2015

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	YU Bo
	WANG Li
	NIU Zheng

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YU Bo,WANG Li,NIU Zheng. Progress in construction of remote sensing and geological test field for comprehensive application and resources evaluation in Hami, Xinjiang[J]. REMOTE SENSING FOR LAND & RESOURCES, 2015, 27(2): 8-14.

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https://www.gtzyyg.com/EN/10.6046/gtzyyg.2015.02.02 OR https://www.gtzyyg.com/EN/Y2015/V27/I2/8

[1] 荀毓龙.遥感基础试验与应用[M].北京:中国科学技术出版社,1991. Xun Y L.The Test and Application of Remote Sensing[M].Beijing:China Science and Technology Press,1991.
[2] 丁暄,童庆禧,郑兰芬,等.光谱遥感找矿理论、技术与应用[J].地球化学,1992(1):1-8. Ding X,Tong Q X,Zheng L F,et al.The theory of spectral remote sensing technique and its application in mineral resource exploration[J].Geochimica,1992(1):1-8.
[3] 白云来.新疆哈密黄山—镜儿泉镍铜成矿系统的地质构造背景[J].甘肃地质学报,2000,9(2):1-7. Bai Y L.Geotectonic settings of Huangshan—Jingerquan nickel-copper metallogenic system in Hami,Xinjiang[J].Acta Geologica Gansu,2000,9(2):1-7.
[4] 董连慧,屈迅,朱志新,等.新疆大地构造演化与成矿[J].新疆地质,2010,28(4):351-357. Dong L H,Qu X,Zhu Z X,et al.Tectonic evolution and metallogenesis of Xinjiang,China[J].Xinjiang Geology,2010,28(4):351-357.
[5] 韩春明,毛景文,杨建民,等.东天山晚古生代内生金属矿床类型和成矿作用的动力学演化规律[J].地质学报,2002,76(2):222-234. Han C M,Mao J W,Yang J M,et al.Types of late palaeozoic endogenetic metal deposits and related Geodynamical evolution in the east Tianshan[J].Acta Geologica Sinica,2002,76(2):222-234.
[6] 毛景文,杨建民,韩春明,等.东天山铜金多金属矿床成矿系统和成矿地球动力学模型[J].地球科学:中国地质大学学报,2002,27(4):413-424. Mao J W,Yang J M,Han C M,et al.Metallogenic systems of polymetallic copper and gold deposits and related metallogenic geodynamic model in eastern Tianshan,Xinjiang[J].Earth Science:Journal of China University of Geosciences,2002,27(4):413-424.
[7] 李小文.地物的二向性反射和方向谱特征[J].环境遥感,1989,4(1):205-219. Li X W.Bidirectional reflectance and angular signature of objects[J].Remote Sensing of Environment,1989,4(1):205-219.
[8] 张宗贵.地物光谱测试方法与标准数据生成方法报告[R].北京:中国土资源航空物探遥感中心,1995. Zhang Z G.Report on Methodology of Ground Object Spectral Measurement and Standard Data Generation[R].Beijing:China Aero Geophysical Survey and Remote Sensing Center for Land and Resources,1995.

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