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Main Authors: Yang, Qiang, Xie, Weilin, Wang, Congfan, Li, Bowen, Li, Xin, Zheng, Xiang, Wei, Wei, Dong, Yi
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.19368
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author Yang, Qiang
Xie, Weilin
Wang, Congfan
Li, Bowen
Li, Xin
Zheng, Xiang
Wei, Wei
Dong, Yi
author_facet Yang, Qiang
Xie, Weilin
Wang, Congfan
Li, Bowen
Li, Xin
Zheng, Xiang
Wei, Wei
Dong, Yi
contents In distributed fiber-optic sensing based on optical frequency domain reflectometry (OFDR), Doppler frequency shifts due to the changes of disturbances during one sweep period introduce demodulation errors that accumulate along both the distance and time, impairing the sensing performance. Here, we report distributed dynamic strain sensing using Doppler-shift-immune phase-sensitive OFDR based on frequency-tracking and spectrum-zooming with ultra-weak reflection array. Theoretical study has been carried out with the introduction of mismatch coefficient, unveiling quantitatively the impact of Doppler shift. Following a numerical analysis of the proposed method, a retained precision has been experimentally verified regardless of the position mismatch due to the Doppler effect. Doppler-shift-immune sensing for dynamic strains covering continuous spatial resolution over a distance of 1000 m with a 2.5 cm sensing spatial resolution has been demonstrated, verifying the high fidelity promised by the proposed method.
format Preprint
id arxiv_https___arxiv_org_abs_2410_19368
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Dynamic strain sensing using Doppler-shift-immune phase-sensitive OFDR with ultra-weak reflection array and frequency-tracking
Yang, Qiang
Xie, Weilin
Wang, Congfan
Li, Bowen
Li, Xin
Zheng, Xiang
Wei, Wei
Dong, Yi
Optics
Applied Physics
In distributed fiber-optic sensing based on optical frequency domain reflectometry (OFDR), Doppler frequency shifts due to the changes of disturbances during one sweep period introduce demodulation errors that accumulate along both the distance and time, impairing the sensing performance. Here, we report distributed dynamic strain sensing using Doppler-shift-immune phase-sensitive OFDR based on frequency-tracking and spectrum-zooming with ultra-weak reflection array. Theoretical study has been carried out with the introduction of mismatch coefficient, unveiling quantitatively the impact of Doppler shift. Following a numerical analysis of the proposed method, a retained precision has been experimentally verified regardless of the position mismatch due to the Doppler effect. Doppler-shift-immune sensing for dynamic strains covering continuous spatial resolution over a distance of 1000 m with a 2.5 cm sensing spatial resolution has been demonstrated, verifying the high fidelity promised by the proposed method.
title Dynamic strain sensing using Doppler-shift-immune phase-sensitive OFDR with ultra-weak reflection array and frequency-tracking
topic Optics
Applied Physics
url https://arxiv.org/abs/2410.19368