Coherent optical frequency domain reflectometry using phase-decorrelated reflected and reference lightwaves

Kohji Tsuji; Kaoru Shimizu; Tsuneo Horiguchi; Yahei Koyamada

doi:10.1109/50.596955

Coherent optical frequency domain reflectometry using phase-decorrelated reflected and reference lightwaves

Kohji Tsuji, Kaoru Shimizu, Tsuneo Horiguchi, Yahei Koyamada

Research output: Contribution to journal › Article › peer-review

16 Citations (Scopus)

Abstract

We report a new scheme for coherent optical frequency domain reflectometry (C-OFDR) where the coherence length of the lightwaves does not limit the measurable fiber length. In this scheme, we use the beat spectrum which results when we mix reflected and reference lightwaves whose phases are not correlated. We demonstrated this scheme using a narrow-linewidth-lightwave source and an external electro-optical phase modulator. We measured Rayleigh backscattering and Fresnel reflections from a 30-km optical fiber, and achieved a spatial resolution of 5 m for two neighboring Fresnel reflectors located at the far end of the fiber. We estimated the expected spatial resolution and single-way dynamic range for our new scheme and show that it is capable of measuring long optical fibers with high-spatial resolution.

Original language	English
Pages (from-to)	1102-1109
Number of pages	8
Journal	Journal of Lightwave Technology
Volume	15
Issue number	7
DOIs	https://doi.org/10.1109/50.596955
Publication status	Published - 1997 Jul

Keywords

Electrooptic modulation
Frequency domain analysis
Heterodyning
Linear FM
Optical fiber measurements
Optical scattering

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics

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10.1109/50.596955

Cite this

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title = "Coherent optical frequency domain reflectometry using phase-decorrelated reflected and reference lightwaves",

abstract = "We report a new scheme for coherent optical frequency domain reflectometry (C-OFDR) where the coherence length of the lightwaves does not limit the measurable fiber length. In this scheme, we use the beat spectrum which results when we mix reflected and reference lightwaves whose phases are not correlated. We demonstrated this scheme using a narrow-linewidth-lightwave source and an external electro-optical phase modulator. We measured Rayleigh backscattering and Fresnel reflections from a 30-km optical fiber, and achieved a spatial resolution of 5 m for two neighboring Fresnel reflectors located at the far end of the fiber. We estimated the expected spatial resolution and single-way dynamic range for our new scheme and show that it is capable of measuring long optical fibers with high-spatial resolution.",

keywords = "Electrooptic modulation, Frequency domain analysis, Heterodyning, Linear FM, Optical fiber measurements, Optical scattering",

author = "Kohji Tsuji and Kaoru Shimizu and Tsuneo Horiguchi and Yahei Koyamada",

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T1 - Coherent optical frequency domain reflectometry using phase-decorrelated reflected and reference lightwaves

AU - Tsuji, Kohji

AU - Shimizu, Kaoru

AU - Horiguchi, Tsuneo

AU - Koyamada, Yahei

PY - 1997/7

Y1 - 1997/7

N2 - We report a new scheme for coherent optical frequency domain reflectometry (C-OFDR) where the coherence length of the lightwaves does not limit the measurable fiber length. In this scheme, we use the beat spectrum which results when we mix reflected and reference lightwaves whose phases are not correlated. We demonstrated this scheme using a narrow-linewidth-lightwave source and an external electro-optical phase modulator. We measured Rayleigh backscattering and Fresnel reflections from a 30-km optical fiber, and achieved a spatial resolution of 5 m for two neighboring Fresnel reflectors located at the far end of the fiber. We estimated the expected spatial resolution and single-way dynamic range for our new scheme and show that it is capable of measuring long optical fibers with high-spatial resolution.

AB - We report a new scheme for coherent optical frequency domain reflectometry (C-OFDR) where the coherence length of the lightwaves does not limit the measurable fiber length. In this scheme, we use the beat spectrum which results when we mix reflected and reference lightwaves whose phases are not correlated. We demonstrated this scheme using a narrow-linewidth-lightwave source and an external electro-optical phase modulator. We measured Rayleigh backscattering and Fresnel reflections from a 30-km optical fiber, and achieved a spatial resolution of 5 m for two neighboring Fresnel reflectors located at the far end of the fiber. We estimated the expected spatial resolution and single-way dynamic range for our new scheme and show that it is capable of measuring long optical fibers with high-spatial resolution.

KW - Electrooptic modulation

KW - Frequency domain analysis

KW - Heterodyning

KW - Linear FM

KW - Optical fiber measurements

KW - Optical scattering

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Coherent optical frequency domain reflectometry using phase-decorrelated reflected and reference lightwaves

Abstract

Keywords

ASJC Scopus subject areas

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