基于功率合成技术的166 GHz大功率源研制
Design of a 166 GHz high power source based on power-combined technology
查看参考文献12篇
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文摘
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冰云探测对于提高天气预报准确性、监测极端天气现象等具有重要的意义.考虑到冰云粒子尺寸、形状分布等因素,利用太赫兹频段被动遥感仪器能更好地解决冰云探测的难题.664 GHz作为一个重要的探测频点,其接收机射频前端主要包括664 GHz二次谐波混频器、332 GHz二倍频器以及166 GHz大功率源.作者在太赫兹二倍频设计的基础上,利用两路功率合成技术实现166 GHz大功率源,目的是提供给后级的332 GHz二倍频器足够的输入功率,从而能够驱动谐波混频器工作.实验结果表明,上述大功率源在164 ~ 172 GHz频率范围内输出功率大于46 mW;在168 GHz处有最大输出功率59 mW.以上研究有效解决了本振链路中G波段输出功率不足的问题,为研制更高频段的太赫兹系统提供了技术支撑. |
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其他语种文摘
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Ice clouds measurement technology plays an important role in improving the accuracy of the weather forecast and monitoring extreme weather phenomena and so on.Considering the physical dimension and shape distribution of ice-cloud particles,the problem of ice-clouds detecting could be solved by using terahertz passive remote sensing instrument.As an important detecting channel,the 664 GHz RF front-end of receiver mainly includes a 664 GHz sub-harmonic mixer,a 332 GHz doubler and a 166 GHz high power source.Based on the design of terahertz doubler,a 166 GHz high power frequency multiplying source has been realized by using two way power-combined technologies.The measured results show that the output power of above-mentioned source is more than 46 mW in 164 ~ 172 GHz and the highest output power is 59 mW at 168 GHz.The above-mentioned research could solve the problem of lacking of the G band high power source in the LO chain,and provide technical support for the design of terahertz system working at higher frequency. |
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来源
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红外与毫米波学报
,2018,37(5):608-612 【核心库】
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DOI
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10.11972/j.issn.1001-9014.2018.05.014
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关键词
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功率合成技术
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二倍频
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大功率源
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地址
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中国科学院国家空间科学中心, 中国科学院微波遥感重点实验室, 北京, 100190
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南京信息工程大学电子与信息工程学院, 江苏, 南京, 210044
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语种
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中文 |
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文献类型
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研究性论文 |
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ISSN
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1001-9014 |
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学科
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物理学 |
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基金
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民用航天技术预先研究项目
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文献收藏号
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CSCD:6360851
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参考文献 共
12
共1页
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1.
王虎. 星载太赫兹冰云探测技术发展和面临问题.
太赫兹科学与电子信息学报,2017,15(5):722-727
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被引
4
次
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|
|
|
2.
Brian P M. Design of a Sub-Millimetre Wave Airborne Demonstrator for Observations of Precipitation and Ice Clouds.
Antennas and Propagation Society International Symposium,2009
|
被引
1
次
|
|
|
|
|
3.
张德海. 425GHz星载结构前端研制.
全国遥感遥测遥控学术年会,2017
|
被引
1
次
|
|
|
|
|
4.
Goutam Chattopadhyay. An All-Solid-State Broad-Band Frequency Multiplier Chain at 1500 GHz.
IEEE Transactions on Microwave Theory and Techniques,2004,52(5):1538-1547
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被引
8
次
|
|
|
|
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5.
Alain Maestrini. Terahertz Sources Based on Frequency Multiplication and Their Applications.
Frequenz,Journal of RF-Engineering and Telecommunications,2008:118-122
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被引
1
次
|
|
|
|
|
6.
赵鑫. 基于肖特基二极管的450GHz二次谐波混频器.
红外与毫米波学报,2015,34(3):301-306
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被引
6
次
|
|
|
|
|
7.
蒋均. 基于Schottky二极管和Hammer-Head滤波器0.67 THz二次谐波混频器.
红外与毫米波学报,2016,35(4):418-424
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被引
7
次
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|
|
|
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8.
Gupta M S. Degradation of power combining efficiency due to variability among signal sources.
IEEE Trans on Microwave Theory and Techniques,1992,40(5):1031-1034
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被引
2
次
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|
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9.
Siles Jose V. A Single-Waveguide In-Phase Power-Combined Frequency Doubler at 190 GHz.
IEEE Microwave and wireless components letters,2011:1-3
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被引
2
次
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|
|
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10.
Maestrini A. In-Phase Power-Combined Frequency Triplers at 300 GHz.
IEEE Microwave and Wireless Component Letter,2008:218-220
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被引
1
次
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11.
Yao Changfei. 150 GHz and 180 GHz fixed-tuned frequency multiplying sources with planar Schottky diodes.
J. Infrared Millim. Waves,2013,32(2):102-107
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被引
2
次
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|
|
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12.
Bertrand Thomas. Application of substrate transfer to a 190GHz frequency doubler and 380GHz sub-harmonic mixer using MMIC foundry Schottky diodes.
Proceedings of the International Society for Optical Engineering,2008
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被引
1
次
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