A Novel Radio on Fiber System for Frequency 32-Tupling Millimeter-Wave Generation and Transmission Using Polarization Modulators

IF 0.6 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC

Journal of Nanoelectronics and Optoelectronics Pub Date : 2023-07-01 DOI:10.1166/jno.2023.3462

Xin-Qiao Chen, Wen-Yao Ba, Xiao-Rui Liu, Kai-Xian Liu, Si-Yuan Dai, Xu Chen

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引用次数: 0

Abstract

A new radio on fiber (ROF) scheme for generation and transmission frequency 32-tupling millimeter-wave (MMW) is proposed. At the central station (CS), six PoIMs are used to construct the ±16 order sidebands generator which can generate ±16 order sidebands. The sideband of +16th order is separate out by an optical interleaver from the output of ±16 order sidebands generator first, then the data of down-link signal is modulated on it. At the base station (BS), a portion sideband of −16th order from the down-link optical signal is separted out with a fiber Bragg grating (FBG) first, then the up-link data is modulated on it for carrier reuse. The remaining ±16th order sidebands from the FBG are beat in a photodetector (PD), then the frequency 32-tupling MMW signal with the down-link data is generated. The key part of this system is the ±16th order sideband generator, in which the ±16th order sidebands with the carrier component can be generated by adjusting the amplitudes and initial phases of the radio frequency (RF) signals loaded on the PoIMs, and the carrier can be cancelled by two 1×2 optical coupler with adjustable splitting ratio and 180° optical phase shifter (OPS). The principle of operation to generate frequency 32-tupling is theoretically analyzed and verified by simulation experiments. The optic sideband suppression ratio (OSSR) of the generated sidebands of ±16th order from the theoretical derivation and experiments are 29.974 dB and 29.793 dB, respectively, the RF spurious suppression ratio (RFSSR) of the obtained frequency 32-tupling MMW from theoretical derivation and experiment are 23.960 dB and 23.814 dB, respectively, which verifies the feasibility of our method. The transmission experiments are carried out. For 30 km fiber with 2.5 Gbps data rate, the Q value and power penalty for up-link and down-link are greater than 6 and less than 0.4 dB, respectively.

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利用偏振调制器产生和传输32倍频率毫米波的新型光纤无线电系统

提出了一种新的32倍毫米波产生和传输频率的光纤无线电(ROF)方案。在中控站(CS)，采用6个poim构成±16阶边带发生器，可产生±16阶边带。先用光交织器从±16阶边带发生器输出中分离出+16阶边带，然后在其上调制下行信号数据。在基站(BS)中，首先用光纤布拉格光栅(FBG)从下行光信号中分离出- 16阶的部分边带，然后在其上调制上行数据以供载波重用。剩余的±16阶边带在光电探测器(PD)中进行拍频，然后产生带有下行链路数据的32倍频毫米波信号。该系统的关键部分是±16阶边带发生器，通过调节加载在PoIMs上的射频信号的幅值和初始相位，产生带有载波分量的±16阶边带，并通过两个可调分割比1×2光耦合器和180°光移相器抵消载波分量。对产生32倍频的工作原理进行了理论分析，并通过仿真实验进行了验证。理论推导和实验得到的±16阶边带的光学边带抑制比(OSSR)分别为29.974 dB和29.793 dB，理论推导和实验得到的32倍频毫米波的射频杂散抑制比(RFSSR)分别为23.960 dB和23.814 dB，验证了方法的可行性。并进行了传输实验。对于数据速率为2.5 Gbps的30km光纤，上行链路和下行链路的Q值和功率损失分别大于6 dB和小于0.4 dB。

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来源期刊

Journal of Nanoelectronics and Optoelectronics 工程技术-工程：电子与电气

自引率

16.70%

发文量

审稿时长

12.5 months