用于星载太赫兹波被动遥感卷云参数的通道辐射特性及反演影响因素研究
李书磊, 刘磊, 高太长, 石立华, 邱实, 胡帅. 用于星载太赫兹波被动遥感卷云参数的通道辐射特性及反演影响因素研究[J]. 红外与毫米波学报, 2018, 37(1): 60.
LI Shu-Lei, LIU Lei, GAO Tai-Chang, SHI Li-Hua, QIU Shi, HU Shuai. Radiation characteristics of the selected channels for cirrus remote sensing in terahertz waveband and the influence factors for the retrieval method[J]. Journal of Infrared and Millimeter Waves, 2018, 37(1): 60.
[1] Mendrok J, Baron P, Yasuko K. Studying the potential of Terahertz radiation for deriving ice cloud microphysical information[C]. Remote Sensing of Clouds and the Atmosphere XIII, 2008: p710704.
[2] Evans K F, Walter S J, Heymsfield A J, et al. Submillimeter-wave cloud ice radiometer: simulations of retrieval algorithm performance[J]. Journal of Geophysical Research,2002, 107(D3): 4028.
[3] Evans K F, Wang J R, Racette P E, et al. Ice cloud retrievals and analysis with the Compact Scanning Submillimeter Imaging Radiometer and the Cloud Radar System during CRYSTAL-FACE[J]. Journal of Applied Meteorology, 2005, 44: 839-859.
[4] Liebe H J. MPM—An atmospheric millimeter-wave propagation model[J]. International Journal of Infrared and Millimeter Waves, 1989, 10(6): 631-650.
[5] Evans K F, Walter S J, Heymsfield A J, et al. Modeling of submillimeter passive remote sensing of cirrus clouds[J]. Journal of Applied Meteorology, 1998, 37: 184-205.
[6] Gasiewski A J. Numerical sensitivity analysis of passive EHF and SMMW channels to tropospheric water vapor, clouds, and precipitation[J]. IEEE Transactions on Geoscience and Remote Sensing, 1992, 30(5): 859-870.
[7] Evans K F, Evans A H, Nolt I G, et al. The prospect for remotesensing of cirrus clouds with a submillimeter-wave spectrometer[J]. Journal of Applied Meteorology, 1999, 38: 514-525.
[8] Rydberg B, Eriksson P, Buehler S A, et al. Non-Gaussian Bayesian retrieval of tropical upper tropospheric cloud ice and water vapor from Odin-SMR measurements[J]. Atmos. Meas. Tech. , 2009, 2: 621-637.
[9] LI Shu-lei, LIU Lei, GAO Tai-chang, et al. Sensitivity analysis of terahertz wave passive remote sensing of cirrus microphysical parameters[J]. Acta. Phys. Sin. (李书磊, 刘磊, 高太长, 等. 太赫兹波被动遥感卷云微物理参数的敏感性试验分析. 物理学报) 2016, 65: 134102.
[10] LI Shu-lei, LIU Lei, GAO Tai-chang, et al. Retrieval method of cirrus microphysical parameters at terahertz wave based on multiple lookup tables[J]. Acta. Phys. Sin., (李书磊, 刘磊, 高太长, 等. 基于多重查找表的太赫兹波段卷云微物理参数的反演方法. 物理学报) 2017, 66: 054102.
[11] Buehler S A, Eriksson P, Kuhn T, et al. ARTS, the atmospheric radiative transfer simulator[J]. Journal of Quantitative Spectroscopy and Radiative Transfer, 2005, 91(1): 65-93.
[12] GU Jun-xi. Dictionary of Atmospheric Science[M]. (大气科学辞典, 顾钧禧). Beijing: China Meteorological Press, 1994: 117.
李书磊, 刘磊, 高太长, 石立华, 邱实, 胡帅. 用于星载太赫兹波被动遥感卷云参数的通道辐射特性及反演影响因素研究[J]. 红外与毫米波学报, 2018, 37(1): 60. LI Shu-Lei, LIU Lei, GAO Tai-Chang, SHI Li-Hua, QIU Shi, HU Shuai. Radiation characteristics of the selected channels for cirrus remote sensing in terahertz waveband and the influence factors for the retrieval method[J]. Journal of Infrared and Millimeter Waves, 2018, 37(1): 60.
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