Microwave applications of photonics circuits

Proceedings., IEEE/Cornell Conference on Advanced Concepts in High Speed Semiconductor Devices and Circuits, Pub Date : 1989-08-07 DOI:10.1109/CORNEL.1989.79850

A. Popa

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引用次数: 1

Abstract

Examples of the use of lightwave circuits to partition airborne systems are presented. The role of lightwave technology in future radar, communication, and electronic warfare system architectures is discussed, with particular reference to the fiber-optic guided missile and aircraft applications. The status of microwave bandwidth lightwave transmitter and receiver circuits operating 1 to 20 GHz is summarized. Laser-current-modulated transmitters are commercially available at 0.83 and 1.3 mu m for modulation frequencies <10 GHz with dynamic ranges >125 dB/Hz. LiNbO/sub 3/-based integrated optic modulators operating in the laboratory at 1.3 mu m can provide dynamic ranges >130 dB/Hz. Optical receivers are commercially available at 0.83 and 1.3 mu m with bandwidths to 10 GHz and dynamic range >130 dB/Hz. Laboratory receivers have operated to 20 GHz with similar performance. The noise floor of the optical portion of lightwave links is typically set by laser noise at a noise figure of about 40 dB. The cascaded noise figure of the link, including input and output amplifiers, is set by the gain and noise figure of the input amplifier, by the noise floor of the laser diode, and by the attenuation encountered through the active and passive optical components in the link.<>

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光子电路的微波应用

给出了使用光波电路对机载系统进行分区的实例。讨论了光波技术在未来雷达、通信和电子战系统架构中的作用，特别提到了光纤制导导弹和飞机的应用。综述了工作频率为1 ~ 20ghz的微波带宽光波收发电路的现状。激光电流调制发射机在商用0.83和1.3 μ m调制频率125 dB/Hz。基于LiNbO/ sub3 /的集成光调制器在实验室工作在1.3 μ m，可以提供bb0 ~ 130 dB/Hz的动态范围。商用光学接收器为0.83和1.3 μ m，带宽为10 GHz，动态范围为>130 dB/Hz。实验室的接收器在20 GHz的频率下工作，具有类似的性能。光波链路的光学部分的噪声底通常由激光噪声设定为约40 dB的噪声系数。链路(包括输入和输出放大器)的级联噪声系数由输入放大器的增益和噪声系数、激光二极管的本底噪声以及通过链路中有源和无源光学元件所遇到的衰减来设定

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Proceedings., IEEE/Cornell Conference on Advanced Concepts in High Speed Semiconductor Devices and Circuits,

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