Technical innovation of optical remote sensing payloads onboard GF-5 satellite

Fan Bin; Chen Xu; Li Bicen; Zhao Yanhua

doi:10.3788/IRLA201746.0102002

The performances and advancements of the two optical payloads, produced by Beijing Institute of Space Mechanics and Electricity, onboard GF-5 satellite were introduced in the paper. The atmosphere environment high-resolution infrared Fourier transform spectrometer had high-resolution, high sun tracking accuracy and high spectral calibration accuracy. Visual and infrared multispectral sensor had high spectral resolution, wide spectral range and high radiometric calibration accuracy. Compared with other similar optical payloads, they were advanced both here and abroad which greatly improved the ability of high-precision observation of China. Key parameters, system composition, key technology, advancements and test results were introdued. At the end of this paper, development direction and enlightenment of follow-up spectrometer were pointed out.

Technical innovation of optical remote sensing payloads onboard GF-5 satellite

1. Beijing Institute of Space Mechanics and Electricity,Beijing 100094,China

Received Date: 2016-05-11

Rev Recd Date: 2016-06-20

Publish Date: 2017-01-25

Key words:

hyperspectral /
remote-sensing /
GF-5

Abstract: The performances and advancements of the two optical payloads, produced by Beijing Institute of Space Mechanics and Electricity, onboard GF-5 satellite were introduced in the paper. The atmosphere environment high-resolution infrared Fourier transform spectrometer had high-resolution, high sun tracking accuracy and high spectral calibration accuracy. Visual and infrared multispectral sensor had high spectral resolution, wide spectral range and high radiometric calibration accuracy. Compared with other similar optical payloads, they were advanced both here and abroad which greatly improved the ability of high-precision observation of China. Key parameters, system composition, key technology, advancements and test results were introdued. At the end of this paper, development direction and enlightenment of follow-up spectrometer were pointed out.

HTML

Reference (9)

[1]	Marc-Andre Soucy, Francois Chateauneuf, Christophe Deutsch, et al. ACE-FTS instrument detailed design[C]//SPIE, 2002:4814:12-16.
[2]	Bernath Peter F. Atmospheric chemistry experiment (ACE):Mission overview[C]//SPIE, 2004:5542:25-32.
[3]	Louis Moreau, Marc-Andr Soucy, Henry Buijs, et al. ACE-FTS instrument:after five years on-orbit[C]//SPIE, 2008:7082:95-101.
[4]	Roland Gessner, Smith David J. Manfred Kolm, et al.MIPAS onboard ENVISAT:flight model performance, calibration and characterization[C]//SPIE, 2001:4169:118-122.
[5]	Reinhard Beer, Glavich Thomas A, Rider David M, Tropospheric emission spectrometer for the Earth Observing System's Aura satellite[J]. Applied Optics, 2001, 40(15):116-121.
[6]	Blumstein D, Chalon G, Carlier T, et al. IASI instrument:technical overview and measured performances[C]//SPIE, 2004, 5543:56-60.
[7]	Duan Pengfei, Li Ming, Xu Pengmei. Effect of tiny vibration to interferometer[J]. Spacecraft Recovery Remote Sensing, 2004, 34(6):88-92. (in Chinese)段鹏飞, 李明, 徐彭梅. 微振动对干涉仪运动机构均匀性的影响分析[J].航天返回与遥感, 2013, 34(6):88-92.
[8]	Feng Zhongkui, Ye Xiaoduan. Landsat7 quick format data products[J]. Remote Sensing Technology and Applications, 2000, 15(4):270-272. (in Chinese)冯钟葵, 叶晓端. Landsat7. 卫星快速格式数据产品[J]. 遥感技术与应用, 2000, 15(4):270-272.
[9]	Zhao Yanhua, Dong Jianting, Zhang Xiuqian, et al. Diffuse reflection board full view radiation calibration technology[J].Spacecraft Recovery Remote Sensing, 2016, 37(2):92-99. (in Chinese)赵艳华, 董建婷, 张秀茜, 等.漫反射板全光路全视场全口径在轨辐射定标技术研究[J]. 航天返回与遥感, 2016, 37(2):92-99.

Technical innovation of optical remote sensing payloads onboard GF-5 satellite

doi: 10.3788/IRLA201746.0102002

Abstract

References

Proportional views

通讯作者: 陈斌, bchen63@163.com

Article Metrics

Related

Proportional views