Photonics for airborne phased array radars

Proceedings 2000 IEEE International Conference on Phased Array Systems and Technology (Cat. No.00TH8510) Pub Date : 2000-05-21 DOI:10.1109/PAST.2000.858979

D. Dolfi, D. Mongardien, S. Tonda, M. Schaller, J. Chazelas

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引用次数: 17

Abstract

In future generation phased array radars, signal distributions will have to fulfil strict performance criteria. These include high isolation from both electromagnetic interference and crosstalk between module or subarray feeds with increased instantaneous bandwidths, dramatic reduction in size and weight with respect to current radars, and performance compatible with growing requirements such as low phase noise and high dynamic range. Photonics and microwave technologies offers new opportunities for controlling many thousands of array elements together with handling the wide bandwidth of shared aperture antennas. Photonics technologies will provide an interconnect solution for future airborne phased array radar antennas, which have conformality, bandwidth, EMI immunity, size,and weight requirements increasingly difficult, if not impossible, to meet using conventional electrical interconnect methods. Future system requirements are reported together with results of newly developed high performance wideband analog microwave links and of demonstrated approaches for true time delay architectures.

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机载相控阵雷达光子学

在未来一代相控阵雷达中，信号分布必须满足严格的性能标准。这些优点包括对电磁干扰和模块或子阵列馈电之间的串扰的高度隔离，具有更高的瞬时带宽，相对于当前雷达的尺寸和重量显着减小，以及与低相位噪声和高动态范围等日益增长的要求相兼容的性能。光子学和微波技术为控制数千个阵列元素以及处理共享孔径天线的宽带提供了新的机会。光子学技术将为未来机载相控阵雷达天线提供互连解决方案，这些天线具有一致性、带宽、EMI抗扰度、尺寸和重量要求，如果不是不可能的话，使用传统的电气互连方法将越来越难以满足。报告了未来的系统需求，以及新开发的高性能宽带模拟微波链路和演示的真实时延架构方法的结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Proceedings 2000 IEEE International Conference on Phased Array Systems and Technology (Cat. No.00TH8510)

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