光纤压力传感器测量的最小偏差腔长解调算法

doi:10.3969/j.issn.1000-1158.2023.08.13

摘要
图/表
参考文献(19)
相关文章 (15)

全文: PDF (539 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要在光纤传感技术领域应用基于法珀腔(外腔式法布里-珀罗干涉腔)结构的光纤压力传感器进行气体压力测量时,由于传感器结构决定了腔长动态范围相对较小,需要高分辨率的腔长测量方法。因此针对基于法珀腔结构的光纤压力传感器进行绝对腔长解调算法研究,提出一种高精度最小偏差腔长解调算法,通过将法珀腔光纤压力传感器密封在压力标准源中,对等间隔压力变化产生的不同腔长进行实时解调,实现了气体压力的实时测量。实验结果表明,法珀腔光纤压力传感器腔长值随压差变化呈现出良好的线性关系和重复性,腔长测量的重复性为±1nm,精度为0.1496%,压力测量的重复性为0.12%,压力测量的精度优于0.5%。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	申雅峰
	江毅
	隋广慧

关键词 ：计量学, 压力测量, 光纤传感器, 外腔式法布里-珀罗干涉腔, 腔长解调

Abstract：When the gas pressure measurement is performed with fiber optic pressure sensors based on EFPI structures, a high-resolution cavity length measurement method is required, because the sensor structure determines that the dynamic range of the cavity length is relatively small. A high precision minimum-deviation cavity-length demodulation algorithm is proposed and experimentally demonstrated. The absolute cavity length of an optical fiber pressure sensor based on EFPI structure is recovered by using the demodulation algorithm. Through sealing an EFPI fiber optic pressure sensor in a pressure standard source, the real-time measurement of gas pressure is realized. The experimental results show that the cavity length of the EFPI fiber pressure sensor has a good linear relationship and repeatability with the change of pressure. The repeatability of cavity length measurement is±1nm, the nonlinear error is 0.1496%,the repeatability of pressure measurement is 0.12%, and the accuracy of pressure measurement is better than 0.5%.

Key words： metrology pressure measurement fiber optic sensors extrinsic Fabry-Perot interferometer cavity length demodulation

收稿日期: 2022-09-21 发布日期: 2023-08-22

PACS:

TB935

基金资助:国家自然科学基金(U20B2057)

通讯作者: 江毅(1967-),四川宜宾,北京理工大学教授,博士生导师,主要从事光纤传感技术与光纤测量仪器方面的研究。Email:bitjy@bit.edu.cn E-mail: syf4400@163.com

作者简介: 申雅峰(1985-),陕西米脂人,北京长城计量测试技术研究所高级工程师,在读博士研究生,主要从事光纤传感测量技术方面的研究。Email:syf4400@163.com

引用本文:

申雅峰,江毅,隋广慧. 光纤压力传感器测量的最小偏差腔长解调算法[J]. 计量学报, 2023, 44(8): 1235-1239.
SHEN Ya-feng,JIANG Yi,SUI Guang-hui. Minimum-deviation Demodulation Algorithm for Measurement of Fiber Optic Pressure Sensors. Acta Metrologica Sinica, 2023, 44(8): 1235-1239.

链接本文:

http://jlxb.china-csm.org:81/Jwk_jlxb/CN/10.3969/j.issn.1000-1158.2023.08.13 或 http://jlxb.china-csm.org:81/Jwk_jlxb/CN/Y2023/V44/I8/1235

	Liu L, Zhou F D, The measurement of gas-liquid tow-phase flowrate by using cross correlation analysis［J］. Acta Metrologica Sinica, 1994, 15(2): 126-131.
［5］	刘铁根, 王双, 江俊峰, 等. 航空航天光纤传感技术研究进展［J］. 仪器仪表学报, 2014, 35(8): 1681-1692.
［1］	Murphy K A, Gunther M F, Vengsarkar A M, et al. Quadrature phase-shifted extrinsic Fabry-Perot optic fiber sensors［J］. Optics Letters, 1991, 24(6): 273-275.
	Chen J L, Kong D M, Hao H, et al. A new type of optical fiber sensor for multi-phase detection in petroleum production［J］. Acta Metrologica Sinica, 2022, 43(8): 1036-1043.
	Liu T G, Wang S, Jiang J F, et al. Advances in optical fiber sensing technology for aviation and aerospace application［J］. Chinese Journal of Scientific Instrument, 2014, 35(8): 1681-1692.
［7］	Wang Z, Jiang Y. Wavenumber scanning-based fourier transform white-light interferometry ［J］. Applied Optics, 2012, 51(22): 5512-5516.
［9］	高庆, 朱勇, 雷小华, 等. 光纤珐珀-光栅传感器通用解调系统研究［J］. 仪器仪表学报, 2004, 25(4): 196-208.
［10］	章鹏, 王军, 朱永, 等. 基于DSP的新型光纤法珀传感解调系统宰［J］. 仪器仪表学报, 2007, 28(3): 437-440.
［12］	Rao Y J. Recent progress in fiber-optic extrinsic Fabry-Perot interferometric sensors［J］. Optical Fiber Technology, 2006, 12(3): 227-237.
［13］	黄彩霞, 张立喆. 一种EFPI光纤压力传感器的结构分析及零点稳定性［J］. 计测技术, 2014, 34(2): 6-10.
［14］	江毅, 张树桓. 光纤激光干涉测量技术在EFPI传感器信号解调中的研究进展［J］. 激光与光电子学进展, 2021, 58(13): 1-13.
［15］	张慧君. 膜片式光纤动态压力传感器的研制［J］. 计测技术, 2022, 42(3): 30-35.
［16］	张慧君, 隋广慧. 基于CO2激光焊接的高温光纤压力传感器的研制［J］. 计测技术, 2021, 41(3): 30-33.
［3］	陈基亮, 孔德明, 郝虎, 等. 一种石油生产多分相检测新型光纤传感器［J］. 计量学报, 2022, 43(8): 1036-1043.
［4］	王志芳, 王书涛, 王贵川, 等. 空芯光子晶体带隙光纤用于甲烷检测的研究［J］. 计量学报, 2019, 40(6): 1135-1139.
［11］	江毅. 高级光纤传感技术［M］. 北京: 科学出版社, 2009: 162-167.
［17］	江毅, 唐才杰. 光纤Fabry-Perot干涉仪原理及应用［M］. 北京: 国防工业出版社, 2009: 176-178.
［2］	刘磊, 周芳德. 气液两相流流量的互相关测量［J］. 计量学报, 1994, 15(2): 126-131.
	Wang Z F, Wang S T, Wang G C, et al. Research on the detection of methane using hollow photonic band gap fiber［J］. Acta Metrologica Sinica, 2019, 40(6): 1135-1139.
［8］	Jiang Y, Ding W. Recent developments in fiber optic spectral white-light interferometry［J］. Photonic Sensors, 2011, 1(1): 62-71.
	Gao Q, Zhu Y, Lei X H, et al. Study on all-purpose demodulation system for fiber fabra-perot sensors and fiber bragg grating sensors［J］. Chinese Journal of Scientific Instrument, 2004, 25(4): 196-208.
	Zhang P, Wang J, Zhu Y, et al. Novel demodulation system of optical fiber Fabry-Perot sensor based on DSP［J］. Chinese Journal of Scientific Instrument, 2007, 28(3): 437-440.
	Jiang Y, Zhang S H. Research progress on fiber optical laser interferometry in signal demodulation of EFPI sensor［J］. Laser & Optoelectronics Progress, 2021, 58(13): 1-13.
	Zhang H J. Development of diaphragm-type optical fiber dynamic pressure sensors［J］. Metrology and Measurement Technology, 2022, 42(3): 30-35.
	Zhang H J, Sui G H. Development of high temperature optical fiber pressure sensor based on CO2 laser welding［J］. Metrology and Measurement Technology, 2021, 41(3): 30-33.
	Jiang Y, Gao H C, Jia J S. Fiber optical spectral-domain whit-light interferometry［J］. Metrology and Measurement Technology, 2018, 38(3): 31-42.
	Shen Y F, Hu C Y, Zhang L. A peak location algorithm for the demodulation spectrum of fiber bragg grating［J］. Optical Technique, 2014, 40(1): 53-57.
［6］	荆振国. 白光非本征法布里-珀罗干涉光纤传感器及其应用研究［D］. 大连: 大连理工大学, 2006.
	Huang C X, Zhang L Z. A type of EFPI fiber pressure sensor based on fabry-perot interferometer and zero drift ［J］. Metrology and Measurement Technology, 2014, 34(2): 6-10.
［19］	申雅峰, 胡春艳, 张磊. 一种光纤波长解调光谱峰值定位算法［J］. 光学技术, 2014, 40(1): 53-57.
［18］	江毅, 高红春, 贾景善. 光谱域光纤白光干涉测量技术［J］. 计测技术, 2018, 38(3): 31-42.