中国地球观测遥感卫星发展现状及文献分析
Development status and literature analysis of China’s earth observation remote sensing satellites
- 2020年24卷第5期 页码:479-510
纸质出版日期: 2020-05-07
DOI: 10.11834/jrs.20209464
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孙伟伟,杨刚,陈超,常明会,黄可,孟祥珍,刘良云.2020.中国地球观测遥感卫星发展现状及文献分析.遥感学报,24(5): 479-510
Sun W W,Yang G,Chen C,Chang M H,Huang K,Meng X Z and Liu L Y. 2020. Development status and literature analysis of China’s earth observation remote sensing satellites. Journal of Remote Sensing(Chinese). 24(5): 479-510
近40年来,中国的地球观测遥感卫星技术发展取得了卓越的成就,已经形成了陆地、气象和海洋3大卫星系统,正在广泛服务于中国的自然资源调查、海洋环境保护、气象灾害预测和国家重大工程等诸多领域。本文回顾了3大卫星系统的发展历程,剖析中国地球观测遥感卫星的发展现状与内在特点,归纳总结在轨卫星的文献研究热点。研究发现,中国3大遥感卫星系统的发展并不均衡,气象卫星业务较为成熟,陆地卫星发展最为迅速。遥感卫星的文献研究数量总体偏少,应用研究亟待提升。后续规划和发展应考虑陆地卫星的轨道高度差异性和波谱范围的互补性,同时增加气象和海洋卫星数量,提升卫星传感器的探测能力和时空分辨率,尤其是加快海洋卫星的业务应用能力。此外,学者们需要进一步加大国产遥感卫星数据的使用力度,加强卫星遥感数据的应用研究以进一步提升中国地球观测遥感卫星的业务能力与国际影响力。
Over the past 40 years
China has attained remarkable achievements in the development of earth observation remote sensing satellite technology. At present
the country has established three main satellite systems
including terrestrial
meteorological
and marine systems
which have been widely used in numerous applications
such as natural resource investigation
marine environmental protection
weather disaster prediction
and other major national projects. This study reviews the development history of the three major satellite systems
analyzes the development status and inherent characteristics of China’s Earth observation remote sensing satellites
and implements the CiteSpace software to summarize the research hotspot literature for all in-orbit remote sensing satellites. The terrestrial remote sensing satellite system has developed rapidly
especially in terms of small commercial satellites. Terrestrial remote sensing satellites comprise four series
including the ZiYuan
GaoFen
HuanJing/ShiJian
and other small satellites. Satellite sensors are rich
and their high spatiotemporal resolution can reach up to 0.5 m. However
they can encounter typical problems
such as uneven development
close-proximity orbital heights
and overlapping spectral ranges in similar sensors. The development of the meteorological remote sensing satellite system is the most mature among the three satellite systems. Two series of polar orbiting and stationary satellites can well detect most atmospheric elements. However
meteorological satellites are few
the spatiotemporal resolution of their sensors is relatively low
and current sensors cannot finely detect certain critical elements
such as the atmospheric wind field. The marine remote sensing satellite system has likewise made significant progress. It consists of three major satellite patterns
namely
marine water color
marine dynamic environment
and marine surveillance and monitoring satellites
which can achieve large-scale simultaneous observation of Chinese marine environments. However
this system also consists of few marine satellites
limited sensor observation elements
and low satellite sensor spatiotemporal resolution. Moreover
hotspot literature analysis shows that the total number of studies on China’s Earth observation satellites is relatively small. The disproportional ratio of articles indexed by SCI and CNKI is serious
especially on the GaoFen and ZiYuan terrestrial satellites. Numerous studies on China’s Earth satellites focus on data processing
but the application aspect is relatively weak and uneven.
Therefore
the future launching of terrestrial remote sensing satellites to develop new sensors
such as lidars
is suggested. Furthermore
different orbital heights as well as the complementarity of the spectral range of different sensors should be considered. The meteorological system should launch additional satellites to carry out networking observations
improve detection capabilities for all meteorological elements
and promote the spatiotemporal resolution of new sensors to meet the refined requirements of weather forecasting and disaster monitoring. The marine remote sensing satellite system should likewise launch more satellites and shorten the launching cycle of similar satellites
improve detection capabilities for marine elements
promote the spatiotemporal resolution of new sensors
and accelerate its transformation from scientific to business-oriented research. Finally
researchers should be encouraged to utilize domestic satellite data and explore relevant studies to promote the advanced techniques of China’s Earth observation satellites.
中国地球观测遥感陆地卫星气象卫星海洋卫星文献分析
China’s earth observationremote sensingterrestrial satellitemeteorological satellitemarine satelliteliterature analysis
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