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K波段辐射计的超宽带多通道接收机设计与实现 被引量:1

Design and Implementation of an Ultra-Wideband Multichannel Receiver for K-Band Radiometer
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摘要 K波段微波高光谱辐射计应用于大气探测方向,能够在高湿度条件下改善大气温湿度廓线精度。为解决传统辐射计接收机未考虑在微波高光谱条件下频谱测量时间和系统复杂度增加的问题,设计与实现了一种用于K波段微波高光谱辐射计的超宽带多通道线性接收机。通过结合传统微波辐射计接收机的数项优点,改进的接收机结构拥有良好的宽带谱特性、高线性度和短频谱测量时间。在18~26 GHz频率范围内,接收机的实测频率增益为77~80 dB、噪声系数为2.1~3.2 dB、线性度为0.999~0.9999和频谱测量时间平均为5.8 ms。实测结果表明,设计的高频谱分辨率接收机适合K波段微波高光谱辐射计在大气遥感和快速天气变化观测中应用。 When used in atmospheric probing,a K-band hyperspectral microwave radiometer can improve the accuracy of temperature and moisture profiling under high humidity condition .But the measuring time is longer and system complexity of traditional radiometer receiver is relatively larger under hyperspectral microwave condition .An ultra-wideband multichannel linear receiver was designed .By combining several advantages of traditional microwave radiometer receiver,the proposed receiver architecture has good wideband performance,high linearity,and short measuring time .At 18 to 26 GHz RF,the performance of measured receiver has a power gain of 77 to 80 dB,a noise factor of 2.1 to 3.2 dB,a linearity of 0.999 to 0.9999,and a multichannel measuring time of 5.8 ms.The measurement results show that the proposed receiver is suitable for K-band hyperspectral microwave radiometer applications .
作者 谢衍 陈敬熊 苗俊刚
机构地区 北京航空航天大学电子信息工程学院
出处 《电光与控制》 北大核心 2014年第4期48-51,共4页 Electronics Optics & Control
基金 国家自然科学基金(41105007)
关键词 微波高光谱技术 微波辐射计接收机 频谱分辨率 超宽带 hyperspectral microwave technology microwave radiometer receiver spectral resolution ultra-wideband
分类号 V271.4 [航空宇航科学与技术—飞行器设计] TP732.1 [自动化与计算机技术—检测技术与自动化装置]
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参考文献10

  • 1常进,陶午沙,粘永健,滕书华.基于双向预测的高光谱图像无损压缩[J].电光与控制,2010,17(10):65-67. 被引量:4
  • 2SMITH W L. Atmospheric soundings from satellites—falseexpectation or the key to improved weather prediction[J].The Royal Meteorological Society, 1991, 117 ( 498 ) : 267-297.
  • 3BLACKWELL W J, LESLIE R V,PIEPER M L, et al. Hy-perspectral microwave atmospheric sounding [J]. IEEETransactions on Geoscience and Remote Sensing, 2011, 49(1):128-142.
  • 4JANSSEN M A. A new instrument for the determination ofradio path delay due to atmospheric water vapor[J]. IEEETransactions on Geoscience and Remote Sensing, 1985, 23(4) :485-490.
  • 5STRAUB C, MURK A, KAMPFER N,et al. Developmentof a 22 GHz correlating radiometer for the observation ofstratospheric water vapor [C] //Microwave Radiometryand Remote Sensing of the Environment, 2008:1-4.
  • 6EL-SHARKAWY A M,SOTIRIADIS P P, BOTTOMLEY PA,et al. A new RF radiometer for absolute noninvasivetemperature sensing in biomedical applications [C]//IEEE International Symposium on Circuits and Sys-tems, 2007 ;329-332.
  • 7TANNER A B. Development of a high stability water vaporradiometer[J]. Radio Science, 1998, 33(2) :449-462.
  • 8TARONGf J M,CAMPS A, PULIDO J A. K-band radio-meter designed for academic purposes : Intercomparison ofperformances as total power, dicke or noise injection radi-ometers [C] //IEEE International Geoscience and RemoteSensing Symposium, 2007 : 2927-2930.
  • 9BLACKWELL W J, GALBRAITH C, HANCOCK T, et al.Design and analysis of a hyperspectral microwave receiversubsystem [C] //Geoscience and Remote Sensing Sympo-sium, 2012:3435-3438.
  • 10KLEMETSEN O, BIRKELUND Y, JACOBSEN S K, etal. Design of medical radiometer front-end for improvedperformance[J]. Progress in Electromagnetics ResearchB,2011,27:289-306.

二级参考文献13

  • 1刘春红,赵春晖,张凌雁.一种新的高光谱遥感图像降维方法[J].中国图象图形学报(A辑),2005,10(2):218-222. 被引量:81
  • 2ZHANG Jing,LIU Guizhong.An efficient reordering prediction-based lossless compression algorithm for hyperspectral images[J].IEEE Geoscience and Remote Sensing Letters,2007,4(2):283-287.
  • 3MIELIKAINEN J,TOIVANEN P.Clustered DPCM for the lossless compression of hyperspectral images[J].IEEE Transactions on Geoscience and Remote Sensing,2003,41(12):2943-2946.
  • 4CHEN Y S,ZHANG Y,ZHANG P,et al.Optimal recursive bidirection prediction for hyperspectral image compression[C]//Proceedings of International Symposium on Instrumentation Science and Technology,2006:313-317.
  • 5TATE S R.Band ordering in lossless compression of multispeetral images[J].IEEE Trans on Computers,1997,46(4):477-483.
  • 6MOTTA G,RIZZO F,STORER J A.Hyperspectral data compression[M].USA:Springer Press,2006.
  • 7RAO A K,BHARGAVA S.Multispectral data compression using bidirectional interband prediction[J].IEEE Transactions on Geoscience and Remote Sensing,1996,34(2):385-397.
  • 8DRAGOTTI P L,POGGI G,RAGOZINI A R P.Compression of multispectral images by three-dimensional SPIHT algorithm[J].IEEE Transactions on Geoscience and Remote Seining,2000,38(1):416-428.
  • 9苏令华,程翥,万建伟.基于同类邻点预测的高光谱图像无损压缩[J].信号处理,2007,23(4):544-547. 被引量:7
  • 10孙蕾,罗建书.基于多波段谱间预测的高光谱图像无损压缩算法[J].电子与信息学报,2007,29(12):2876-2879. 被引量:14

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电光与控制
2014年 第4期

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