Multi-Static Multi-Band Synthetic Aperture Radar (SAR) Constellation Based on Photonic Processing

2022 IEEE International Topical Meeting on Microwave Photonics (MWP) Pub Date : 2022-10-01 DOI:10.1109/MWP54208.2022.9997654

M. Reza, S. Maresca, F. Scotti, G. Pandey, Muhammad Imran, G. Serafino, M. Amir, Federico Camponeschi, P. Ghelfi, A. Bogoni, M. Scaffardi

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Abstract

Multi-static SARs from low earth orbits (LEO) allow single-pass high-resolution imaging and detection of moving targets. A coherent MIMO approach requires the generation of multi-band orthogonal signals, the fusion of which increases the system resolution. Up to now the synchronization capability of SAR signals of different satellites is critical. Here we propose the use of photonics to generate, receive and distribute the radar signals in a coherent multi-static SAR constellation. Photonics overcomes issues in implementation of MIMO SAR, allowing for flexible multi-band signals generation and centralized generation in a primary satellite with coherent distribution to all the secondary satellites of the SAR signals through FSO links. The numerical analysis shows the proposed system has noise equivalent sigma zero (NESZ) <−31.6 dB, satisfying the SAR system requirements. An experimental proof of concept based on commercial bulk devices, for both radar signal up and down conversion is implemented, demonstrating the system functionality.

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基于光子处理的多静态多波段合成孔径雷达星座

来自低地球轨道(LEO)的多静态sar允许单次高分辨率成像和检测移动目标。相干MIMO方法需要产生多波段正交信号，这些正交信号的融合提高了系统的分辨率。目前，不同卫星SAR信号的同步能力至关重要。本文提出利用光子学技术在相干多静态SAR星座中产生、接收和分配雷达信号。光子学克服了MIMO SAR实施中的问题，允许灵活的多波段信号生成和集中生成，并通过FSO链路将SAR信号相干分布到所有辅助卫星。数值分析表明，该系统噪声等效σ零(NESZ) < - 31.6 dB，满足SAR系统要求。基于商用批量设备的概念验证实验，实现了雷达信号的上下转换，展示了系统的功能。

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2022 IEEE International Topical Meeting on Microwave Photonics (MWP)

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