[1] R. C. Willson. Total solar irradiance trend during solar cycles 21 and 22[J]. Science, 1997, 277(5334): 1963~1965
[2] M. Fligge, S. Solanki. The solar spectral irradiance since 1700[J]. Geophys. Res. Lett., 2000, 27(14): 2157~2160
[3] G. Rottman. Measurement of total and spectral solar irradiance[J]. Space Sci. Rev., 2006, 125(1-4): 39~51
[4] J. Lean. Variations in the sun′s radiative output[J]. Rev. Geophys., 1991, 29(4): 505~535
[5] Zhang Jiaqi, Qi Jin, Fang Wei et al.. Correction of observation angle in solar radiation monitor[J]. Acta Optica Sinica, 2011, 31(2): 0212003
[6] J. London, G. J. Rottman, T. N. Woods et al.. Time variations of solar UV irradiance as measured by the SOLSTICE (UARS) instrument[J]. Geophys. Res. Lett., 1993, 20(12): 1315~1318
[7] G. Thuillier, M. Hersé, P. Simon. Observation of the UV solar irradiance between 200 and 350 nm during the ATLAS-1 mission by the SOLSPEC spectrometer[J]. Solar Physics, 1997, 171(2): 283~302
[8] G. Rottman, G. Mount, G. Lawrence et al.. Solar spectral irradiance measurements: visible to near-infrared regions[J]. Metrologia, 1998, 35(4): 707~712
[9] J. Lean. Contribution of ultraviolet irradiance variations to changes in the sun′s total irradiance[J]. Science, 1989, 244(4901): 197~200
[11] Wu Lianghai, Gao Jun, Fan Zhiguo et al.. Scattering of particles in the atmosphere and their influence on celestial polarization patterns[J]. Acta Optica Sinica, 2011, 31(7): 0701005
[12] Hao Zengzhou, Gong Fang, Pan Delu et al.. Scattering and polarization characteristics of dust aerosol particles [J]. Acta Optica Sinica, 2012, 32(1): 0101002
[13] J. D. Haigh. CLIMATE: climate variability and the influence of the sun[J]. Science, 2001, 294(5549): 2109~2111
[14] D. Rind. The sun′s role in climate variations[J]. Science, 2002, 296(5568): 673~677
[15] J. D. Haigh. The impact of solar variability on climate[J]. Science, 1996, 272(5264): 981~984
[16] C. Frhlich, B. N. Andersen, T. Appourchaux et al.. First results from VIRGO, the experiment for helioseismology and solar irradiance monitoring on SOHO[J]. Solar Physics, 1997, 170(1): 1~25
[17] G. Thuillier, M. Hersé, P. C. Simon et al.. The visible solar spectral irradiance from 350 to 850 nm as measured by the SOLSPEC spectrometer during the ATLAS I mission[J]. Solar Phys., 1998, 177(1): 41~61
[18] G. Thuillier, M. Hersé, D. Labs et al.. The solar spectral irradiance from 200~2400 nm as measured by the SOLSPEC spectrometer from the ATLAS and EURECA missions[J]. Solar Phys., 2003, 214(1): 1~22
[19] H. Bovensmann, J. Burrows, M. Buchwitz et al.. SCIAMACHY: Mission objectives and measurement modes[J]. J. Atmospheric Sciences, 1999, 56(2): 127~150
[20] J. Skupin, S. Noel, M. W. Wuttke et al.. SCIAMACHY solar irradiance observation in the spectral range from 240~2380 nm[J]. Adv. in Space Res., 2005, 35(3): 370~375
[21] T. Woods, G. Rottman, J. Harder et al.. Overview of the EOS SORCE mission[C]. SPIE, 2000, 4135: 192~203
[22] J. Harder, G. Lawrence, G. Rottman et al.. The spectral irradiance monitor (SIM) for the SORCE mission[C]. SPIE, 2000, 4135: 204
[23] J. Harder, G. Lawrence, J. Fontenla et al.. The spectral irradiance monitor: scientific requirements, instrument design, and operation modes[J]. Solar Phys., 2005, 230(1-2): 141~167
[24] G. Rottman, J. Harder, J. Fontenla et al.. The spectral irradiance monitor (SIM): early observations[J]. Solar Phys., 2005, 230(1-2): 205~224
[25] C. Féry. A prism with curved faces, for spectrograph or spectroscope [J]. Astrophysical J., 1911, 34: 79
[26] D. Warren, J. Hackwell, D. Gutierrez. Compact prism spectrographs based on aplanatic principles[J]. Opt. Engng., 1997, 36(4): 1174~1182
[27] I. Malitson. Interspecimen comparison of the refractive index of fused silica[J]. J. Opt. Soc. Am., 1965, 55(10): 1205~1208
[28] Fang Wei, Wang Yupeng, Liang Jingqiu et al.. New type detector that may be a standard of instrument[J]. Infrared and Laser Engineering, 2007, 36(S2): 517~520
[30] P. Wilksch. Instrument function of the Fabry-Perot spectrometer[J]. Appl. Opt., 1985, 24(10): 1502~1511
[31] P. Mouroulis, R. O. Green, T. G. Chrien. Design of pushbroom imaging spectrometers for optimum recovery of spectroscopic and spatial information[J]. Appl. Opt., 2000, 39(13): 2210~2220