Noise analysis and SNR optimization design of fiber optical current transformers

2020 IEEE Sustainable Power and Energy Conference (iSPEC) Pub Date : 2020-11-23 DOI:10.1109/iSPEC50848.2020.9351215

Hu Bei, Xiao Hao, Xiao Jingen, Lai JiaCang, Liu Jianguang, L. Boyang

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引用次数: 6

Abstract

Optical Fiber Current Transformer (FOCT) is susceptible to various types of noise, which leads to a decrease in its measurement accuracy, especially when the primary current is small. Improving its signal-to-noise ratio is one of the key technologies of FOCT. This article comprehensively analyzes FOCT's optical signal noise, signal detection noise and noise sources introduced by the external environment, and gives the calculation method of FOCT SNR. The influence of different noise sources on the signal-to-noise ratio is simulated through theory, and the FOCT signal-to-noise ratio optimization design plan is proposed. It is pointed out that the receiver optical power can be increased, increasing the number of sensitive optical fibers of the sensor head and selecting the appropriate closed-loop feedback phase modulation bias operating point method can effectively improve the signal-to-noise ratio and has been verified by experiments. Based on this design FOCT prototype, rated current of 600 A when meet GB / T 20840.8-2007 predetermined 0.2S level requirements, and the SNR is 30.2dB at 1% rated current, the ratio error is less than 0.61%, the phase error is less than 12.39′.

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光纤电流互感器噪声分析及信噪比优化设计

光纤电流互感器容易受到各种噪声的影响，导致其测量精度下降，特别是在一次电流较小的情况下。提高其信噪比是傅里叶变换的关键技术之一。本文综合分析了FOCT的光信号噪声、信号检测噪声和外部环境引入的噪声源，给出了FOCT信噪比的计算方法。通过理论模拟了不同噪声源对信噪比的影响，提出了fft信噪比优化设计方案。指出提高接收机光功率、增加传感头敏感光纤数量和选择合适的闭环反馈调相偏置工作点方法可以有效提高信噪比，并通过实验进行了验证。基于本设计的fft样机，额定电流为600 A时满足GB / T 20840.8-2007预定的0.2S电平要求，且在1%额定电流下信噪比为30.2dB，比值误差小于0.61%，相位误差小于12.39’。

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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2020 IEEE Sustainable Power and Energy Conference (iSPEC)

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