Hollow Core Bragg Fiber-based Gas Pressure Sensor Using Parallel Fabry-Perot Interferometers

2022 IEEE 7th Optoelectronics Global Conference (OGC) Pub Date : 2022-12-06 DOI:10.1109/OGC55558.2022.10051007

Zongru Yang, Weihao Yuan, Changyuan Yu

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Abstract

An ultra-high sensitivity parallel-connected Fabry-Perot interferometers (FPIs) pressure sensor based on hollow core Bragg fiber (HCBF) and harmonic Vernier effect is proposed and demonstrated. One FPI (FPI-1) acts as the sensing unit while the other FPI (FPI-2) is used as the reference unit to generate the Vernier effect. The FPI-1 was prepared by fusion splicing a section of HCBF between a single-mode fiber (SMF) and a hollow silica tube (HST), and the FPI-2 was fabricated by sandwiching a piece of HCBF between two SMFs. Two FPIs with very different free spectral ranges (FSR) in the fringe pattern were connected to the 3-dB coupler parallelly, which realizes the harmonic Vernier effect and ensures the stability of the interference fringe. Both measurements of the air pressure in the range of 0-0.24 MPa and the temperature in the range of 25-55 °C were conducted using the dual FPIs sensor. Experimental results exhibited that high sensitivity of 124.35 nm/MPa with excellent linearity of 0.9967 was achieved by the sensing probe. Moreover, the calculated temperature crosstalk was as low as ~0.072 kPa/°C. The proposed sensor can be a promising candidate for real-time and high-precision gas pressure monitoring.

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采用平行法布里-珀罗干涉仪的空芯布拉格光纤气体压力传感器

提出并演示了一种基于空芯布拉格光纤(HCBF)和谐波游标效应的超高灵敏度并联法布里-珀罗干涉仪压力传感器。一个FPI (FPI-1)作为传感单元，而另一个FPI (FPI-2)作为参考单元来产生游标效果。FPI-1是通过在单模光纤(SMF)和空心硅管(HST)之间熔接一段HCBF制备的，FPI-2是通过在两个单模光纤(SMF)之间夹接一块HCBF制备的。将条纹图中自由频谱范围(FSR)相差很大的两个fpi并联到3db耦合器上，实现了谐波游标效应，保证了干涉条纹的稳定性。采用双fpi传感器对0-0.24 MPa范围内的气压和25-55℃范围内的温度进行测量。实验结果表明，该传感探针的灵敏度为124.35 nm/MPa，线性度为0.9967。计算得到的温度串扰低至~0.072 kPa/℃。该传感器可用于实时、高精度的气体压力监测。

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2022 IEEE 7th Optoelectronics Global Conference (OGC)

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