Mode-Walk-off Interferometry for Position-Resolved Optical Fiber Sensing

Costa, Luís; Zhan, Zhongwen; Marandi, Alireza

doi:10.1109/jlt.2022.3216533

Cited by 3 publications

(2 citation statements)

References 56 publications

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“…Long-haul transoceanic cables, however, introduce unique challenges that cannot be tackled using the prevailing techniques applied for in-land cables (i.e., distributed optical fiber sensing 5 , 9 ). These methods often rely on weakly backscattered light, which restricts their application to the first ~100 km of cable, makes them incompatible with optical repeaters 10 , and elicits the use of high optical peak powers (leading to optical nonlinearities which compromise coexisting data channels in the same fiber strand 11 ). These limitations are often inconsequential for in-land or near-shore deployments, as the total cable lengths are shorter and the abundance of unused fiber strands facilitates the use of dedicated sensing fibers, but constitute critical roadblocks for transoceanic deployments.…”

Section: Introductionmentioning

confidence: 99%

Localization of seismic waves with submarine fiber optics using polarization-only measurements

Costa,

Varughese,

Mertz

et al. 2023

Commun Eng

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Monitoring seismic activity on the ocean floor is a critical yet challenging task, largely due to the difficulties of physical deployment and maintenance of sensors in these remote areas. Optical fiber sensing techniques are well-suited for this task, given the presence of existing transoceanic telecommunication cables. However, current techniques capable of interrogating the entire length of transoceanic fibers are either incompatible with conventional telecommunication lasers or are limited in their ability to identify the position of the seismic wave. In this work, we propose and demonstrate a method to measure and localize seismic waves in transoceanic cables using only conventional polarization optics, by launching pulses of changing polarization. We demonstrate our technique by measuring and localizing seismic waves from a magnitude Mw 6.0 earthquake (Guerrero, Mexico) using a submarine cable connecting Los Angeles, California and Valparaiso, Chile. Our approach introduces a cost-effective and practical solution that can potentially increase the density of geophysical measurements in hard-to-reach regions, improving disaster preparedness and response, with minimal additional demands on existing infrastructure.

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Section: Introductionmentioning

confidence: 99%

Localization of seismic waves with submarine fiber optics using polarization-only measurements

Costa,

Varughese,

Mertz

et al. 2023

Commun Eng

Self Cite

View full text Add to dashboard Cite

show abstract

“…Long-haul transoceanic cables, however, introduce unique challenges that cannot be tackled using the prevailing techniques applied for in-land cables (i.e., distributed optical fiber sensing 5,9 ). These methods often rely on weakly backscattered light, which restricts their application to the first ∼ 100 km of cable, makes them incompatible with optical repeaters 10 , and elicits the use of high optical peak powers (leading to optical nonlinearities which compromise coexisting data channels in the same fiber strand 11 ). These limitations are often inconsequential for in-land or near-shore deployments, as the total cable lengths are shorter and the abundance of unused fiber strands facilitates the use of dedicated sensing fibers, but constitute critical roadblocks for transoceanic deployments.…”

Section: Introductionmentioning

confidence: 99%

Localization of Seismic Waves in Submarine Fiber Optics Using Polarization-only Measurements

Varughese

Mertz

Kamalov

et al. 2023

Preprint

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Monitoring seismic activity on the ocean floor is a critical yet challenging task, largely due to the difficulties of physical deployment and maintenance of sensors in these remote areas. Optical fiber sensing techniques are well-suited for this task, given the presence of existing transoceanic telecommunication cables. However, current techniques capable of interrogating the entire length of transoceanic fibers are either incompatible with conventional telecommunication lasers or are limited in their ability to identify the position of the seismic wave. In this work, we propose and demonstrate a method to measure and localize seismic waves in transoceanic cables using only conventional telecommunication transponders and detectors, by launching pulses of changing polarization. We demonstrate our technique by measuring and localizing seismic waves from a magnitude Mw 6.0 earthquake (Guerrero, Mexico) using a submarine cable connecting Los Angeles, California and Santiago, Chile. Our approach introduces a cost-effective and practical solution that can potentially increase the density of geophysical measurements in hard-to-reach regions, improving disaster preparedness and response, with minimal additional demands on existing infrastructure.

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Distributed Vibration Sensor Based on Mode Coupling in Weakly Coupled Multi-Core Fibers

Cheng,

Zhao,

Chen

et al. 2023

28th International Conference on Optical Fiber Sensors

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Mode-Walk-off Interferometry for Position-Resolved Optical Fiber Sensing

Cited by 3 publications

References 56 publications

Localization of seismic waves with submarine fiber optics using polarization-only measurements

Localization of seismic waves with submarine fiber optics using polarization-only measurements

Localization of Seismic Waves in Submarine Fiber Optics Using Polarization-only Measurements

Distributed Vibration Sensor Based on Mode Coupling in Weakly Coupled Multi-Core Fibers

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