Design and numerical simulation of SPF-PCF-SPF fluid sensing system based on photoelectric oscillator

Junqi Guo; Yiting Yue; Wei Cui; Xinhai Zou; Haoyu Yang; Junkai Yang

doi:10.1007/s11801-022-1159-x

Optoelectronics Letters ›› 2022, Vol. 18 ›› Issue (6) : 326 -330. DOI: 10.1007/s11801-022-1159-x

Article

Design and numerical simulation of SPF-PCF-SPF fluid sensing system based on photoelectric oscillator

Author information +

History +

PDF

Abstract

In this paper, an optical fiber fluid sensing system based on optoelectronic oscillator (OEO) was proposed and studied numerically. The fluid sensor head is constructed by splicing two sections of side-polished fiber (SPF) to one section of photonic crystal fiber (PCF). Fluid sample can flow continuously through the holes of PCF. The refractive index (RI) change of the fluid sample can lead to the effective RI change of the fiber, resulting in frequency change of microwave signal generated by OEO. By monitoring the oscillation frequency using an electronic spectrum analyzer (ESA), the RI of fluid sample can be measured. Thanks to the fast interrogation speed of ESAs, the measuring speed can be increased significantly compared to traditional optical fiber RI sensing systems using optical spectrometers. The sensing principle of the system was studied. The sensitivity of the proposed system was evaluated by simulation, and an RI sensitivity of −14.20 MHz/RIU can be achieved. The results show that with proper system design, real-time RI measurement with high sensitivity can be achieved. Increasing the length of the PCF while under the premise of the fluid parameters will be the most reasonable way to improve the sensitivity. The proposed design and simulation results can provide suggestions for the fabrication and optimization of fluid sensing systems used for real-time detection and measurement of biological elements and heavy metal ions in liquid environment.

Cite this article

Download citation ▾

Junqi Guo, Yiting Yue, Wei Cui, Xinhai Zou, Haoyu Yang, Junkai Yang. Design and numerical simulation of SPF-PCF-SPF fluid sensing system based on photoelectric oscillator. Optoelectronics Letters, 2022, 18(6): 326-330 DOI:10.1007/s11801-022-1159-x

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	DevikaV, RajanM S M. Hexagonal PCF of honeycomb lattice with high birefringence and high nonlinearity[J]. International journal of modern physics B, 2020, 34(10):2050094

[2]	HowladerA H, IslamM S, RazzakS. Proposal for dispersion compensating square-lattice photonic crystal fiber[J]. Optoelectronics letters, 2021, 17(3): 160-164

[3]	ZhangY, ShiC, GuC, et al.. Liquid core photonic crystal fiber sensor based on surface enhanced Raman scattering[J]. Applied physics letters, 2007, 90(19):241

[4]	LiuY, XiaB Q, TanH Y, et al.. Numerical simulation of a neotype fluidic sensing system based on side-polished optical fiber[J]. Optoelectronics letters, 2020, 16(4): 262-267

[5]	LuX L, ZhangX D, ChenN, et al.. A high linearity refractive index sensor based on D-shaped photonic-crystal fiber with built-in metal wires[J]. Optik-international journal for light and electron optics, 2020, 220: 165021

[6]	WangY, HuangQ, ZhuW J, et al.. Novel optical fiber SPR temperature sensor based on MMF-PCF-MMF structure and gold-PDMS film[J]. Optics express, 2018, 26(2):1910-1917

[7]	LuanN N, WangR, LvW H, et al.. Surface plasmon resonance temperature sensor based on photonic crystal fibers randomly filled with silver nanowires[J]. Sensors, 2014, 14(9):16035-16045

[8]	DaryoushA S, PoddarA, SunT, et al.. Optoelectronic oscillators: recent and emerging trends[J]. Microwave journal, 2018, 61(10):58-76

[9]	YaoJ. Optoelectronic oscillator for high speed and high-resolution optical sensing[J]. Journal of lightwave technology, 2017, PP(16):1-1

[10]	PaulD. A review of optoelectronic oscillators for high speed signal processing applications[J]. ISRN electronics, 2013, 2013: 1-16

[11]	NguyenL D, NakataniK, JournetB. Refractive index measurement by using an optoelectronic oscillator[J]. IEEE photonics technology letters, 2020, 22(12):857-859

[12]	LiuJ, WangM, TangY, et al.. Switchable optoelectronic oscillator using an FM-PS-FBG for strain and temperature sensing[J]. IEEE photonics technology letters, 2017, 29(23):2008-2011

[13]	YangY, WangM, ShenY, et al.. Refractive index and temperature sensing based on an optoelectronic oscillator incorporating a Fabry-Perot fiber Bragg grating[J]. IEEE photonics journal, 2018, 10(1):1-9

[14]	WuB L, WangM G, DongY, et al.. Magnetic field sensor based on a dual-frequency optoelectronic oscillator using cascaded magneto strictive alloy-fiber Bragg grating-Fabry Perot and fiber Bragg grating-Fabry Perot filters[J]. Optics express, 2018, 26(21):27628-27638

[15]	GaoW L, ZhangW H, TongZ G, et al.. Refractive index and temperature sensor based on optical fiber Mach-Zehnder interferometer with trapezoid cone[J]. Optical engineering, 2019, 58(5):057102.1-057102.5

[16]	SeunghunL, HyerinS, HeesangA, et al.. Fiber-optic localized surface plasmon resonance sensors based on nanomaterials[J]. Sensors, 2021, 21(3):819

[17]	ChenX, XiaL, LiC. Surface plasmon resonance sensor based on a novel D-shaped photonic crystal fiber for low refractive index detection[J]. IEEE photonics journal, 2018, 10(1): 1-9

[18]	PandaA, PukhrambamP D. Design and analysis of porous core photonic crystal fiber based ethylene glycol sensor operated at infrared wavelengths[J]. Journal of computational electronics, 2021, 20(4):1-15