Strain Transfer Function of Distributed Optical Fiber Sensors and Back-Calculation of the Base Strain Field

Distributed optical fiber sensors are a promising technology for monitoring the structural health of large-scale structures. The fiber sensors are usually coated with nonfragile materials to protect the sensor and are bonded onto the structure using adhesive materials. However, local deformation of...

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Main Authors: Sangyoung Yoon, Meadeum Yu, Eunho Kim, Jaesang Yu
Format: Article
Language:English
Published: MDPI AG 2021-05-01
Series:Sensors
Subjects:
Online Access:https://www.mdpi.com/1424-8220/21/10/3365
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spelling doaj-49aff95072694cea98dcc4b4b1e308b02021-05-31T23:49:54ZengMDPI AGSensors1424-82202021-05-01213365336510.3390/s21103365Strain Transfer Function of Distributed Optical Fiber Sensors and Back-Calculation of the Base Strain FieldSangyoung Yoon0Meadeum Yu1Eunho Kim2Jaesang Yu3Division of Mechanical System Engineering, Jeonbuk National University, Jeonbuk 54896, KoreaDivision of Mechanical System Engineering, Jeonbuk National University, Jeonbuk 54896, KoreaDivision of Mechanical System Engineering, Jeonbuk National University, Jeonbuk 54896, KoreaDivision of Mechanical System Engineering, Jeonbuk National University, Jeonbuk 54896, KoreaDistributed optical fiber sensors are a promising technology for monitoring the structural health of large-scale structures. The fiber sensors are usually coated with nonfragile materials to protect the sensor and are bonded onto the structure using adhesive materials. However, local deformation of the relatively soft coating and adhesive layers hinders strain transfer from the base structure to the optical fiber sensor, which reduces and distorts its strain distribution. In this study, we analytically derive a strain transfer function in terms of strain periods, which enables us to understand how the strain reduces and is distorted in the optical fiber depending on the variation of the strain field. We also propose a method for back-calculating the base structure’s strain field using the reduced and distorted strain distribution in the optical fiber sensor. We numerically demonstrate the back-calculation of the base strain using a composite beam model with an open hole and an attached distributed optical fiber sensor. The new strain transfer function and the proposed back-calculation method can enhance the strain field estimation accuracy in using a distributed optical fiber sensor. This enables us to use a highly durable distributed optical fiber sensor with thick protective layers in precision measurement.https://www.mdpi.com/1424-8220/21/10/3365distributed optical fiber sensorstrain transfer functionstrain back-calculationstructural health monitoring
collection DOAJ
language English
format Article
sources DOAJ
author Sangyoung Yoon
Meadeum Yu
Eunho Kim
Jaesang Yu
spellingShingle Sangyoung Yoon
Meadeum Yu
Eunho Kim
Jaesang Yu
Strain Transfer Function of Distributed Optical Fiber Sensors and Back-Calculation of the Base Strain Field
Sensors
distributed optical fiber sensor
strain transfer function
strain back-calculation
structural health monitoring
author_facet Sangyoung Yoon
Meadeum Yu
Eunho Kim
Jaesang Yu
author_sort Sangyoung Yoon
title Strain Transfer Function of Distributed Optical Fiber Sensors and Back-Calculation of the Base Strain Field
title_short Strain Transfer Function of Distributed Optical Fiber Sensors and Back-Calculation of the Base Strain Field
title_full Strain Transfer Function of Distributed Optical Fiber Sensors and Back-Calculation of the Base Strain Field
title_fullStr Strain Transfer Function of Distributed Optical Fiber Sensors and Back-Calculation of the Base Strain Field
title_full_unstemmed Strain Transfer Function of Distributed Optical Fiber Sensors and Back-Calculation of the Base Strain Field
title_sort strain transfer function of distributed optical fiber sensors and back-calculation of the base strain field
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2021-05-01
description Distributed optical fiber sensors are a promising technology for monitoring the structural health of large-scale structures. The fiber sensors are usually coated with nonfragile materials to protect the sensor and are bonded onto the structure using adhesive materials. However, local deformation of the relatively soft coating and adhesive layers hinders strain transfer from the base structure to the optical fiber sensor, which reduces and distorts its strain distribution. In this study, we analytically derive a strain transfer function in terms of strain periods, which enables us to understand how the strain reduces and is distorted in the optical fiber depending on the variation of the strain field. We also propose a method for back-calculating the base structure’s strain field using the reduced and distorted strain distribution in the optical fiber sensor. We numerically demonstrate the back-calculation of the base strain using a composite beam model with an open hole and an attached distributed optical fiber sensor. The new strain transfer function and the proposed back-calculation method can enhance the strain field estimation accuracy in using a distributed optical fiber sensor. This enables us to use a highly durable distributed optical fiber sensor with thick protective layers in precision measurement.
topic distributed optical fiber sensor
strain transfer function
strain back-calculation
structural health monitoring
url https://www.mdpi.com/1424-8220/21/10/3365
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