微波信号光学产生,optical generation of microwave signals
1)optical generation of microwave signals微波信号光学产生
2)optical microwave generation光学微波产生
英文短句/例句
1.Advanced Fiber Laser Technology and Its Applications in Optical Sensing & Optical Microwave Generation先进光纤激光器技术及其在光传感、光学微波产生的应用
2.Research on Characteristics of Microwave Signals Generated by Optical Heterodyne光学外差法产生微波信号特性的研究
3.Generation of Broad Band Microwave Pulses by Ultrashort Optical Pulses利用超短光脉冲产生宽频带微波脉冲
4.Microwave Photonic Filters and Their Applications in Microwave Signal Generation and Radio-over-Fiber Systems微波光子滤波器及其在微波信号产生和Radio-over-Fiber系统中的应用
5.Generation of Microwave or Millimeter-wave Based on Polarization Scrambler and Polarization Maintaining Fiber基于扰偏器和保偏光纤的微波毫米波产生研究
6.Tunable photonic microwave generation using optically injected semiconductor laser光注入半导体激光器产生可调谐高频微波
7.Microwave Signal Generation and Processing Based on Electro-optic Phase Modulator基于电光相位调制器的微波信号产生与处理
8.Design of Bi-Directional Radio over Fiber Transmission System Based on Optical Frequency Multiplication基于光学倍乘法产生光毫米波的全双工毫米波光纤传输系统设计
9.Determination of Trace Arsenic in Seafood with Microwave Digestion-atomic and Fluorescence Spectrometry微波消解-原子荧光光谱法测海产品中的微量砷
10.Signal Controlling in an Optical Generation Microwave and Millimeter Wave System光生微波/毫米波系统中信号控制研究
11.THE DETERMINATION OF AS AND HG IN AGRICULTURAL PRODUCTS BY MICROWAVE DIGESTION AND ATOMIC FLUORESCENCE SPECTROSCOPY;微波消解氢化物发生原子荧光法同时测定农产品中砷和汞
12.Diffraction, too, occurs in light waves.衍射也是由光波产生。
13.Microvariability and Spectral Variability in the Optical Bands of Blazars耀变体光学波段的微光变及能谱变化
14.Mid-infrared Wavelength Based on Difference-frequency Generation in Nonlinear Optical Crystals AgGaS_2 and AgGaSe_2;非线性光学晶体AgGaS_2/AgGaSe_2用于差频产生中红外波长
15.The Theoretical Study on the CW and Quasi-CW THz Wave Generation by Optical Method;光学方法产生连续、准连续THz波的理论研究
16.Study of Photonic Generation of Millimeter-wave Signal and Associated Techniques for Radio-over-fiber SystemROF系统中光学产生毫米波及相关技术的研究
17.Theoretic and Experimental Studies of Terahertz Radiation Based on Difference Frequency Generation光学差频产生太赫波的理论与技术研究
18.Any of several devices that amplify or generate electromagnetic waves, especially microwaves.微波激射器扩大或产生电磁波的仪器,尤其是产生微波
相关短句/例句
optical microwave generation光学微波产生
3)microwave photonic signal微波光子信号
1.The principles, characteristics and operations of stimulated Brillouin scattering(SBS) formicrowave photonic signals in optical fiber are summarized.概述了光纤中受激布里渊散射(SBS)作用于微波光子信号的工作原理,基本特性以及工作方式。
2.In this paper,the methods ofmicrowave photonic signal generation are presented,such as electro-optical modulation,heterodyne generation,harmonic frequency generation and optoelectronic oscillator.微波光子信号的产生是微波光子技术的一个基础。
4)optical processing of microwave signals微波信号光处理
5)microwave signal generator微波信号发生器
1.Using Qt/Embedded,Frequency Switching Time(FST) of themicrowave signal generator deceased to 45 ms,single sideband phase noise is-75dBc/Hz,power accuracy is 0.使用Qt/Embedded设计的微波信号发生器频率切换时间达到了45 ms,单边带相位噪声为-75 dBc/Hz,功率准确度为0。
6)microwave signal微波信号
1.Discussion of electric power plant′s electromagnetic influence tomicrowave signal;电厂电磁干扰对微波信号的影响
2.According to ITU proposal,microwave link is used to Ka band,the scheme of transparence transmittingmicrowave signal over laser link was designed,including direct modulation transmission and microwave frequency conversion transmission.采用ITU(国际电信联盟)推荐的Ka波段为星间微波链路的通信频段,设计了采用激光链路透明传输微波信号的系统方案,包括直接微波信号传输和微波信号变频传输的两种方案。
3.In this paper, definition, composition, and key technic in design and implementation of themicrowave signal transmission technology via optical fiber are mainly introduced, and its advantages and military issues can be solved is analysed in detail, Some features of radar signals under 18GHz and key technical indexes、function and structure of characteristic products are presented in the end.介绍了新兴的微波信号光纤传输技术的定义、主要构成、实现方式以及应用的关键技术,并详细分析了它的发展优势及其应用领域,最后给出了实用中的各个频段微波信号的特点及相应各频段光端机的关键技术指标、功能结构。
延伸阅读
磁控光子晶体磁控光子晶体德国物理学家制造了一种可以用磁场来调节的新型光子晶体,其性能优于电调节光子晶体。德国karlsruhe研究院的stefan linden与karlsruhe大学的合作者利用一对金线制成了这个装置,金线的作用是充当人造磁性原子。这个发现为人们在纳米尺度操控光提供了一种新方法。(参考文献:phys.rev.lett. 97 083902)光子晶体是一种某些性质周期性变化的人造纳米结构材料,通常这种材料的电容率(也称介电常数)呈周期性变化,可以产生“光子带隙”从而使光的传播变得可控。其原理类似于周期变化半导体材料产生的控制电流的导带和禁带。光子晶体的实现也是通过有目的的掺杂,使晶体具备控制光传播的能力。在此之前,所有操纵可见光的光子晶体都是通过电信号调节材料的电容率来控制的。虽然从理论上讲也可以通过调节导磁率(μ)来实现这种功能,但是众所周知天然材料对可见光来讲其导磁率μ为1,也就是说,研究者不能通过调节导磁率的方法来制造光子晶体。直到现在,linden与其合作者才发现了一种用超颖材料(metamaterial)解决这个问题的方法。超颖材料是一种用纳米微杆、金属小环等制造的人工纳米结构复合材料,这些纳米小部件在材料中扮演人造原子的角色。超颖材料的性质与它的组件完全不同,包括导磁率μ不等于1。在linden他们目前的实验中,使用了一对被50纳米厚的氟化镁分开的宽为220纳米长为100微米的金线,构造了一个一维人造磁性原子阵列。然后他们将这个装置置于石英底座上,制成了一个可以使光沿特定路线传播的磁光子晶体。linden说:“我们的发现证明了关于存在磁光子晶体的理论,尽管它距实际应用还有相当的距离。”既可以利用电容率也可以利用导磁率,在设计制造光子晶体方面给了科学家们更大的自由度。
