High Sensitivity Strain and Temperature Sensing With Cascaded Sagnac Interferometer Based on Harmonic Vernier Effect

Xin Ding , Shen Liu , Mengjie Wang , Nan Chen , Weiguan Zhang , Yiping Wang

Photonic Sensors ›› 2025, Vol. 15 ›› Issue (3) : 250319

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Photonic Sensors ›› 2025, Vol. 15 ›› Issue (3) : 250319 DOI: 10.1007/s13320-025-0762-4
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High Sensitivity Strain and Temperature Sensing With Cascaded Sagnac Interferometer Based on Harmonic Vernier Effect

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Abstract

To further improve sensor sensitivity, a strain and temperature sensor based on the harmonic Vernier effect with cascaded Sagnac interferometers (SIs) is proposed. Through a combination of simulation and experimentation, it is shown that the basic Vernier effect can be realized when the lengths of the polarization-maintaining fiber (PMF) in two SIs are slightly different. Furthermore, the first-order harmonic Vernier effect can be achieved when the lengths of two PMFs are approximately integer multiples. This sensor, leveraging the harmonic Vernier effect, demonstrates higher sensitivity. Compared to a single SI, the strain sensitivity based on the basic Vernier effect is improved to 61.93 pm/με with a magnification factor of 7.6, and the temperature sensitivity is improved to 14.29 nm/°C with a magnification factor of 9.4. For the first-order harmonic Vernier effect, the strain sensitivity increases to 146.35 pm/με with a magnification factor of 18, and the temperature sensitivity increases to 24.92 nm/°C with a magnification factor of 16.5. Additionally, the sensor based on the harmonic Vernier effect exhibits good stability in strain and temperature measurement. Unlike the basic Vernier effect, the harmonic Vernier effect does not require strict control of the reference and sensing interferometer lengths, further increasing sensitivity. Due to its simple structure and low cost, the proposed sensor shows significant potential for applications in high-precision measurement engineering and medical treatment.

Keywords

Cascade Sagnac interferometers / harmonic Vernier effect / strain and temperature measurement / polarization-maintaining fiber

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Xin Ding, Shen Liu, Mengjie Wang, Nan Chen, Weiguan Zhang, Yiping Wang. High Sensitivity Strain and Temperature Sensing With Cascaded Sagnac Interferometer Based on Harmonic Vernier Effect. Photonic Sensors, 2025, 15(3): 250319 DOI:10.1007/s13320-025-0762-4

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

SerajiE F, AsghariF. Tunable optical filter based on Sagnac phase-shift using single optical ring resonator. Optics & Laser Technology, 2009, 42(1): 115-119

[2]

ArianfardH, WuJ Y, JuodkazisS, MossD J. Advanced multi-functional integrated photonic filters based on coupled Sagnac loop reflectors. Journal of Lightwave Technology, 2021, 39(5): 1400-1408

[3]

KumarN, RamachandranK. Dynamic spectral maneuvering by fiber Sagnac loop filter. Optics & Laser Technology, 2014, 63: 144-147

[4]

PuS L, LuoL F, TangJ L, MiaoL M, ZengX L. Ultrasensitive refractive-index sensors based on tapered fiber coupler with Sagnac loop. IEEE Photonics Technology Letters, 2016, 28(10): 1073-1076

[5]

ShiZ X, ZhangJ B, YangL, WuH, NiY, GongJ, et al.. Miniature optical correlator in a single-nanowire Sagnac loop. ACS Photonics, 2020, 7(11): 3264-3269

[6]

StéphaneB, MichaelB, KrishnanP, MichelD, GordonS K. Pickup suppression in Sagnac-based fiber-optic acoustic sensor array. Journal of Lightwave Technology, 2006, 24(7): 2889-2897

[7]

MoseleyS, ScaramuzzaN, TassonJ, TrostelM L. Lorentz violation and Sagnac gyroscopes. Physical Review D, 2019, 100(6): 064031

[8]

MohammadiM, SeifouriM, OlyaeeS. The rotation sensing based on the Sagnac effect in silicon-integrated optical gyroscope with noise considerations. Optical and Quantum Electronics, 2024, 56: 995

[9]

CapezzutoM, GaudiosiG, NardoneL, D’AlemaE, D’AmbrosioD, ManzoR, et al.. Fiber-optic gyroscope for rotational seismic ground motion monitoring of the Campi Flegrei volcanic area. Applied Optics, 2024, 63(16): 4226-4233

[10]

JiaH X, WheelerJ M, IantoscaT, DigonnetM. Low-drift fiber-optic gyroscope interrogated with multiple broadened semiconductor lasers. Journal of Lightwave Technology, 2024, 42(13): 4666-4673

[11]

DongX Y, TamH Y, ShumP. Temperatureinsensitive strain sensor with polarizationmaintaining photonic crystal fiber based Sagnac interferometer. Applied Physics Letters, 2007, 90(15): 151113

[12]

KimG, ChoT, HwangT K, LeeK, LeeK S, HanY G, et al.. Strain and temperature sensitivities of an elliptical hollow-core photonic bandgap fiber based on Sagnac interferometer. Optics Express, 2009, 17(4): 2481-2486

[13]

ZhaoY F, DaiM L, ChenZ M, LiuX Y, GandhiM S, LiQ, al,et., et al.. Ultrasensitive temperature sensor with Vernier-effect improved fiber Michelson interferometer. Optics Express, 2021, 29(2): 1090-1101

[14]

L. ChenH, ZhuX P, JiangC, LiH, S. GuoX, SunS M. High sensitivity temperature and pressure sensor based on cascaded Fabry-Perot and Sagnac interferometers. Instrumentation Science & Technology, 2022, 50(4): 422-436

[15]

C. DingZ, TanZ W, ZhanP K, ZhangL W. Highly sensitive temperature sensor based on cascaded HiBi-FLMs with the Vernier effect. Journal of the Optical Society of America B, 2020, 37(7): 1948-1955

[16]

L. JiaX, ZhouX F, BiM H, YangG W, HuM M, WangT S. High-sensitivity optical fiber temperature sensor of cascaded FSI and MZI based on Vernier effect. Optical Fiber Technology, 2021, 65: 102625

[17]

LinH F, LiuF F, GuoH Y, ZhouA, DaiY T. Ultra-highly sensitive gas pressure sensor based on dual side-hole fiber interferometers with Vernier effect. Optics Express, 2018, 26(22): 28763-28772

[18]

NanT, LiuB, WuY F, WangJ F, MaoY Y, ZhaoL L, et al.. Ultrasensitive strain sensor based on Vernier-effect improved parallel structured fiber-optic Fabry-Perot interferometer. Optics Express, 2019, 27(12): 17239-17250

[19]

ZhangS X, LiuY, ZhaoY J, ZhouA, YuanL B. Bending sensor with parallel fiber Michelson interferometers based on Vernier-like effect. Optics & Laser Technology, 2019, 120: 105679

[20]

GomesA D, FerreiraM S, BierlichJ, KobelkJ, RothhardtM, BarteltH, et al.. Optical harmonic Vernier effect: a new tool for high performance interferometric fiber sensors. Sensors, 2019, 19(24): 5431

[21]

GomesA D, FerreiraM S, BierlichJ, KobelkJ, RothhardtM, BarteltH, et al.. Hollow microsphere combined with optical harmonic Vernier effect for strain and temperature discrimination. Optics & Laser Technology, 2020, 127: 106198

[22]

YangX M, WuS, H. ChengH, MaJ W, WangS, LiuS H, et al.. Simplified highly-sensitive gas pressure sensor based on harmonic Vernier effect. Optics & Laser Technology, 2021, 140: 107007

[23]

LuoC H, X. ChenX, WuS. Ultrasensitive fiber-based gas pressure sensor based on harmonic Vernier effect with enhanced contrast. Optics & Laser Technology, 2022, 156: 108532

[24]

HeM F, ZhuB B, ZhangZ X. High sensitivity temperature sensor based on harmonic Vernier effect. Photonic Sensors, 2023, 13(2): 230204

[25]

ShaoL Y, LuoY, ZhangZ Y, ZouX H, LuoB, PanW, et al.. Sensitivity-enhanced temperature sensor with cascaded fiber optic Sagnac interferometers based on Vernier-effect. Optics Communications, 2015, 336: 73-76

[26]

ZhangW J, Q. WuX, ZuoC, GuiL, H. ShiJ, ZhaoX N, et al.. Highly sensitive temperature and strain sensor based on fiber Sagnac interferometer with Vernier effect. Optics Communications, 2022, 506: 127543

[27]

GomesA D, BarteltH, FrazãoO. Optical Vernier effect: recent advances and developments. Laser & Photonics Reviews, 2021, 15(7): 2000588

[28]

LiuK G, DingX, LiY, LiuX J, XiaoQ. Dual-parameter sensing of parallel fiber Sagnac interferometer based on vernier effect. IEEE Sensors Journal, 2023, 23(7): 6769-6778

[29]

LiuS, LuG W, LvD Y, ChenM M, ZhangZ X. Sensitivity enhanced temperature sensor with cascaded Sagnac loops based on harmonic Vernier effect. Optical Fiber Technology, 2021, 66: 102654

[30]

XieL Q, ChenM M, ZhangZ X. Simplified highly sensitive temperature sensor based on harmonic Vernier effect. Applied Physics B, 2022, 128(8): 158

[31]

ChenL, TianJ J, WuQ, YaoY. Ultrahigh sensitivity temperature sensor based on harmonic Vernier effect. IEEE Sensors Journal, 2022, 23(1): 381-388

[32]

YangW L, PanR, ZhangL Y, YangY Q, LiL J, YuS, et al.. Highly sensitive fiber-optic temperature sensor with compact hybrid interferometers enhanced by the harmonic Vernier effect. Optics Express, 2023, 31(9): 14570-14582

[33]

YangP, JiangS C, WangZ H, PengX R, PengB J. Enhancing sensor strain sensitivity via simulated reference arm for optical harmonic Vernier effect. IEEE Sensors Journal, 2023, 23(22): 27375-27381

[34]

LiZ R, DangW J, DanJ X, JinK Z, NanP Y, XinG G, et al.. High-sensitivity interferometric high-temperature strain sensor based on optical harmonic Vernier effect. Optical Fiber Technology, 2023, 79: 103361

[35]

LinS Y, WangF, QuY C, HanX P, ZhangY D. High-temperature measurement based on highly-sensitive miniature cascaded FPIs and the harmonic Vernier effect. Measurement, 2023, 221: 113456

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