Towards shape-sensing using time-expanded ΦOTDR

European Workshop on Optical Fibre Sensors Pub Date : 2023-05-23 DOI:10.1117/12.2678431

Camilo Escobar-Vera, M. Soriano-Amat, H. Martins, D. Barrera, S. Martín-López, M. González-Herráez, M. R. Fernandez Ruiz

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Abstract

Optical fiber sensors are becoming a prominent solution to perform shape sensing thanks to their interesting and well-known advantages such as flexibility, lightweight, sensitivity, etc. However, the different approaches commonly used to date, which include fiber Bragg gratings, OFDR or OTDR architectures, are not able to achieve a fully distributed and fast performance over relatively long ranges (e.g., tens of meters) and with fine (cm-scale) resolution. Here, we present a novel scheme to perform curvature sensing attaining all the previously mentioned features by application of time-expanded phase-sensitive (TE-Φ)OTDR technology. TE-ΦOTDR is a promising distributed sensing technique that delivers a performance ranging between that of OFDR and ΦOTDR. As a proof-of-concept, we interrogate three cores of a multicore fiber (MCF) using TE-ΦOTDR, attaining curvature sensing with 10 cm resolution over a maximum measurable range of 125 m and a sampling rate of 50 Hz. The implementation of shape sensing schemes with the performance provided by TE-ΦOTDR technology may open the door to new and interesting applications in civil engineering, medicine and seismology.

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使用时间扩展的形状传感ΦOTDR

光纤传感器由于其灵活、轻便、灵敏等优点，正成为形状传感的重要解决方案。然而，迄今为止常用的不同方法，包括光纤布拉格光栅、OFDR或OTDR架构，都无法在相对较长的距离(例如，几十米)和精细(厘米尺度)分辨率下实现完全分布式和快速的性能。在这里，我们提出了一种新的方案，通过应用时间扩展相敏(TE-Φ)OTDR技术来实现曲率传感，从而获得上述所有特征。TE-ΦOTDR是一种很有前途的分布式传感技术，其性能介于OFDR和ΦOTDR之间。作为概念验证，我们使用TE-ΦOTDR询问多芯光纤(MCF)的三个芯，在125 m的最大可测量范围内获得10厘米分辨率的曲率传感，采样率为50 Hz。具有TE-ΦOTDR技术性能的形状传感方案的实施可能为土木工程、医学和地震学中的新应用打开大门。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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European Workshop on Optical Fibre Sensors

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