A Photonics-Based Superheterodyne RF Reception Approach

Advances in Astronautics Science and Technology Pub Date : 2021-11-17 DOI:10.1007/s42423-021-00089-y

Guangyu Gao, Qijun Liang, Ziyu Liu, Huanfa Peng, Qiang Zhao, Naijin Liu

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引用次数: 1

Abstract

A novel photonics-based RF reception approach is proposed as a competitive solution to meet the current challenges of photonics-based approaches and to realize high performances at the same time. The proposed approach adopts the superheterodyne configuration by a combination manner of electronic techniques and photonic techniques, including the ultra-wideband generation of optical LO, the two-stage photonic superheterodyne frequency conversion and the real-time IF compensation. An engineering prototype has been developed and its performance has been evaluated in the laboratory environment. The experiment results preliminarily verify the feasibility of the proposed approach and its engineering potential. The typical performances are as follows: 0.1 GHz ~ 45 GHz operation spectrum range (> 40 GHz), 900 MHz instantaneous bandwidth, 101 dB·Hz^2/3 SFDR and 130 dB·Hz LDR, image rejections of ~ 80 dB for 1st frequency conversion and > 90 dB for 2nd frequency conversion.

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一种基于光子的超外差射频接收方法

提出了一种新的基于光子的RF接收方法，作为一种有竞争力的解决方案，以应对当前基于光子的方法的挑战，同时实现高性能。该方法采用了电子技术和光子技术相结合的超外差配置，包括超宽带产生光LO、两级光子超外差频率转换和实时中频补偿。已经开发了一个工程样机，并在实验室环境中对其性能进行了评估。实验结果初步验证了该方法的可行性及其工程潜力。典型性能如下：0.1 GHz ~ 45GHz工作频谱范围（>； 40GHz）、900MHz瞬时带宽、101dB·Hz2/3 SFDR和130dB·Hz LDR ~ 第1次频率转换为80 dB >；第二次频率转换为90 dB。

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