Beyond a 10<sup>7</sup> range-resolution<sup>−1</sup> product in an OFDR based on a periodic phase noise estimation method

Chen Zou; Cuofu Lin; Tieliang Mou; Zhangjun Yu; Zhangjun Yu; Yunlong Zhu; Yunlong Zhu; Yao Zhu; Yao Zhu; Fanyang Dang; Fanyang Dang; Fanyang Dang; Yonggui Yuan; Yonggui Yuan; Jun Yang; Jun Yang; Yuncai Wang; Yuncai Wang; Yuwen Qin; Yuwen Qin

doi:10.1364/OL.474017

Optics Letters
Vol. 47,
Issue 20,
pp. 5373-5376
(2022)
•https://doi.org/10.1364/OL.474017

Beyond a 10⁷ range-resolution⁻¹ product in an OFDR based on a periodic phase noise estimation method

Chen Zou, Cuofu Lin, Tieliang Mou, Zhangjun Yu, Yunlong Zhu, Yao Zhu, Fanyang Dang, Yonggui Yuan, Jun Yang, Yuncai Wang, and Yuwen Qin

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Chen Zou, Cuofu Lin, Tieliang Mou, Zhangjun Yu, Yunlong Zhu, Yao Zhu, Fanyang Dang, Yonggui Yuan, Jun Yang, Yuncai Wang, and Yuwen Qin, "Beyond a 10⁷ range-resolution⁻¹ product in an OFDR based on a periodic phase noise estimation method," Opt. Lett. 47, 5373-5376 (2022)

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- Optical Sensors, Measurements, and Metrology
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About this Article
History
- Original Manuscript: August 30, 2022
- Revised Manuscript: September 21, 2022
- Manuscript Accepted: September 22, 2022
- Published: October 11, 2022

Abstract

We present and demonstrate a method based on a periodic phase noise estimation in an optical frequency domain reflectometry (OFDR) capable of a beyond 10⁷ range-resolution⁻¹ product (RRP) for the first time, which corresponds to 2.5 × improvement compared with the state-of-the-art. The moving average filter is employed to suppress the amplification of noise in the derivation process. Further, with the help of a third-order Taylor expansion, this method provides a highly precise estimation of periodic phase noise, which is the main factor impacting the performance of OFDR systems with medium-to-long measurement range combined with a submillimeter spatial resolution. A spatial resolution within 535 $\mathrm{\mu} {\textrm {m}}$ over the measurement range of 8 km is obtained. The proposed method offers a promising technique for fiber network monitoring and sensing applications.

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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Range	Amplitude (dB)			Spatial Resolution ( $μ m$ )
Range	Optimized Deskew Filter	PPNE-Deskew Filter	Promotion	Optimized Deskew Filter	PPNE-Deskew Filter	Promotion
2 m	$- 52.3$	$- 52.3$	0	$527.5$	$527.5$	$0 %$
66 m	$- 48.5$	$- 48.4$	$0.1$	$538.5$	$532.9$	$1.1 %$
1.44 km	$- 60.9$	$- 60.2$	$0.7$	$518.5$	$511.0$	$1.5 %$
3.71 km	$- 62.2$	$- 60.9$	$1.3$	$494.5$	$483.5$	$2.3 %$
5.77 km	$- 61.5$	$- 58.5$	$3.0$	$500.5$	$461.5$	$8.5 %$
7.95 km	$- 52.0$	$- 42.7$	$9.3$	$4300$	$522.0$	$723.8 %$

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