星载臭氧垂直探测仪地外太阳紫外光谱测量

张振铎; 王淑荣

doi:doi:10.3788/lop49.061201

激光与光电子学进展, 2012, 49 (6): 061201, 网络出版: 2012-05-07

星载臭氧垂直探测仪地外太阳紫外光谱测量

Measurement of Extraterrestrial Solar Ultraviolet Spectrum from the Solar Backscatter Ultraviolet Spectrometer

论文大纲

张振铎 ^*王淑荣

作者单位

中国科学院长春光学精密机械与物理研究所，吉林长春 130033

测量光谱测量误差分析光谱比对星载遥感仪器 measunement spectrum measurement uncertainty analysis spectrum comparison satellite-borne remote sensing instrument

摘要

介绍了国内外星载太阳紫外光谱辐射计的研究进展，对我国自行研制的星载臭氧垂直探测仪的结构和功能进行了简介。它是一种小型化、高精度的紫外真空紫外光谱辐射计，可在轨测量获得160~400 nm地外太阳绝对光谱。给出了星载臭氧垂直探测仪实测的地外太阳紫外光谱并对其精度进行了分析。误差分析表明，160~250 nm地外太阳绝对光谱的测量不确定度为±6.4%；250~400 nm为±5.2%。将臭氧垂直探测仪在轨观测结果与国际同类仪器进行了比对，一致性优于±5%。

Abstract

The study process of the satellite-borne solar ultraviolet spectrometer is briefly introduced. The optical and mechanical structures of the ultraviolet spectrometer (SBUS) are introduced. SBUS is a compact, high-precision satellite-borne spectral radiometer. It can measure 160~400 nm solar ultraviolet-spectral irradiance under solar work modes. The calculation method and uncertainty factors of the measured ultraviolet spectral irradiance are analyzed. The measurement uncertainty analysis shows that the total uncertainty of the measured ultraviolet spectral irradiance is ±6.4% at 160~250 nm and ±5.2% at 250~400 nm. The data of solar ultraviolet spectral irradiance obtained by SBUS agree with the internationally published data with the deviation within ±5%.

参考文献

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张振铎, 王淑荣. 星载臭氧垂直探测仪地外太阳紫外光谱测量[J]. 激光与光电子学进展, 2012, 49(6): 061201. Zhang Zhenduo, Wang Shurong. Measurement of Extraterrestrial Solar Ultraviolet Spectrum from the Solar Backscatter Ultraviolet Spectrometer[J]. Laser & Optoelectronics Progress, 2012, 49(6): 061201.

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