[1]
|
Rytír M. Radiowave Propagation at Ka-band (20/30 GHz) for Satellite Communication in High-Latitude Regions[D]. Norway:Norwegian University of Science and Technology, 2009 |
[2]
|
Su Zhenling.Research on Atmospheric Combined Attention Effect on Millimeter Wave System[D]. Xi'an:Xidian University, 2008(苏振玲. 大气复合衰减对毫米波系统的影响研究[D]. 西安电子科技大学, 2008) |
[3]
|
Yang Ruike. Research on Several Electromagnetic(Optical)Wave Propagation Problems on Earth-space Paths in Troposphere Atmosphere[D]. Xi'an:Xidian University, 2003(杨瑞科. 对流层地—空路径电磁(光)波传播的若干问题研究[D]. 西安电子科技大学, 2003) |
[4]
|
Wang L, Gong W, Ma Y, et al. Analysis of Ultraviolet Radiation in Central China from Observation and Estimation[J]. Energy,2013, 59: 764-774 |
[5]
|
Altshuler E E, Marr R A. Cloud Attenuation at Millimeter Wavelengths[J]. Antennas and Propagation, IEEE Transactions on,1989, 37(11): 1 473-1 479 |
[6]
|
Dintelmann F, Ortgies G. Semiempirical Model for Cloud Attenuation Prediction[J]. Electronics Letters,1989, 25(22): 1 487-1 488 |
[7]
|
Salonen E, Uppala S. New Prediction Method of Cloud Attenuation[J]. Electronics Letters,1991, 27(12): 1 106-1 108 |
[8]
|
Omotosho T V, Mandeep J S, Abdullah M. Cloud Cover, Cloud Liquid Water and Cloud Attenuation at Ka and V bands over Equatorial Climate[J]. Meteorological Applications,2014,21(3):777-785 |
[9]
|
Das S, Chakraborty S, Maitra A. Radiometric Measurements of Cloud Attenuation at a Tropical Location in India[J].Journal of Atmospheric and Solar-Terrestrial Physics,2013, 105: 97-100 |
[10]
|
Maitra A, Chakraborty S. Cloud Liquid Water Content and Cloud Attenuation Studies with Radiosonde Data at a Tropical Location[J]. Journal of Infrared, Millimeter, and Terahertz Waves, 2009, 30(4): 367-373 |
[11]
|
Recommendation ITU-R. Attenuation due to Cloud and Fog[J]. ITU-R P, 2009,4:840 |
[12]
|
Mao Tianpeng, Zhou Dongfang, NiuZhongxia, et al.The Calculation Model of the Attention Due to Clouds or Fog and the Analysis of Its Characteristic[J]. Wireless Communication Technology, 2004,3: 51-54(毛天鹏,周东方,牛忠霞,等. 毫米波云雾衰减计算模型及特性分析[J]. 无线通信技术, 2004, 3: 51-54) |
[13]
|
Lian Yi, Chen Shengbo, Meng Zhiguo, et al. Distribution of Microwave Radiation Brightness Temperature on the Lunar Surface Based on Chang'E-2 MRM Data [J]. Geomatics and Information Science of Wuhan University, 2015, 40(6):732-737 (连懿, 陈圣波, 孟治国,等. 利用嫦娥二号微波辐射计数据的全月亮温制图[J]. 武汉大学学报·5信息科学版, 2015, 40(6):732-737) |
[14]
|
Wang Yongqian, Shi Jiancheng, Liu Zhihong, et al. Passive Microwave Remote Sensing of Precipitable Water Vapor over Beijing-Tianjin-Hebei Region Based on AMSR-E[J]. Geomatics and Information Science of Wuhan University, 2015, 40(4):479-486 (王永前, 施建成, 刘志红,等. 利用微波辐射计AMSR-E的京津冀地区大气水汽反演[J]. 武汉大学学报·5信息科学版, 2015, 40(4):479-486) |
[15]
|
Macke A, Kalisch J, Zoll Y, et al. Radiative Effects of the Cloudy Atmosphere from Ground and Satellite Based Observations[C]. EPJ Web of Conference,EDP Sciences, France, 2010 |
[16]
|
Rose T, Crewell S, Löhnert U, et al. A Network Suitable Microwave Radiometer for Operational Monitoring of the Cloudy Atmosphere[J]. Atmospheric Research, 2005, 75(3): 183-200 |
[17]
|
Löhnert U, Maier O. Operational Profiling of Temperature Using Ground-based Microwave Radiometry at Payerne: Prospects and Challenges[J]. Atmospheric Measurement Techniques, 2012, 5(5): 1 121-1 134 |
[18]
|
Löhnert U, Turner D D, Crewell S. Ground-based Temperature and Humidity Profiling Using Spectral Infrared and Microwave Observations. Part I: Simulated Retrieval Performance in Clear-sky Conditions[J]. Journal of Applied Meteorology and Climatology, 2009, 48(5): 1 017-1 032 |
[19]
|
Zhou Xiuji. Atmospheric Microwave Radiation and Principles of Remote Sensing[M]. Beijing:Science Press,1982(周秀骥. 大气微波辐射及遥感原理[M]. 北京:科学出版社, 1982) |
[20]
|
Liebe H J, Hufford G A, Manabe T. A Model for the Complex Permittivity of Water at Frequencies Below 1 THz[J]. International Journal of Infrared and Millimeter Waves,1991, 12(7): 659-675 |