Optical mixing of two optical waves from a helium-neon gas laser to generate a stable continuous-wave radio-frequency signal

2019 International Workshop on Fiber Optics in Access Networks (FOAN) Pub Date : 2019-09-01 DOI:10.1109/FOAN.2019.8933817

Amila Dervišcvić, Ena Kikanović, A. Lavrič, Boštian Batagelj

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Abstract

An approach to the generation of a radio-frequency signal using a dual longitudinal mode helium-neon (HeNe) gas laser and the optical mixing technique is proposed and demonstrated. Several approaches using lasers and photodetectors with different characteristics give a detailed insight into the potential and utility of the optical mixing of two optical waves to generate a radio-frequency reference source. A low-phase-noise radio-frequency signal is observed by a signal-source analyzer because the two lasing modes share the same gain medium in the few-centimeters-long cavity and the relative phase irregular shifting fluctuations between the two wavelengths are low. The observed phase noise below −100 dBc/Hz at the offset of 1 kHz from the continuous-wave tone at the central frequency of 723 MHz indicates that the dual-mode-cavity gas laser efficiently suppresses the wavelength fluctuations between the lightwave modes, enabling a stable radio-frequency signal to be generated.

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将氦氖气体激光器发出的两个光波进行光学混合，以产生稳定的连续波射频信号

提出并演示了一种利用双纵向模氦氖气体激光器和光混合技术产生射频信号的方法。几种使用具有不同特性的激光器和光电探测器的方法，详细介绍了两种光波的光学混合以产生射频参考源的潜力和效用。由于两种激光模式在几厘米长的腔内具有相同的增益介质，并且两种波长之间的相对相位不规则移位波动很小，因此信号源分析仪观测到低相位噪声的射频信号。在中心频率为723 MHz的连续波音调偏移1khz处观测到的相位噪声低于- 100 dBc/Hz，表明双模腔气体激光器有效地抑制了光波模式之间的波长波动，从而产生了稳定的射频信号。

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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2019 International Workshop on Fiber Optics in Access Networks (FOAN)

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