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Main Authors: Roodsari, Samaneh Manavi, Freund, Sara, Angelmahr, Martin, Rauter, Georg, Schade, Wolfgang, Cattin, Philippe C.
Format: Preprint
Published: 2022
Subjects:
Online Access:https://arxiv.org/abs/2210.16316
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author Roodsari, Samaneh Manavi
Freund, Sara
Angelmahr, Martin
Rauter, Georg
Schade, Wolfgang
Cattin, Philippe C.
author_facet Roodsari, Samaneh Manavi
Freund, Sara
Angelmahr, Martin
Rauter, Georg
Schade, Wolfgang
Cattin, Philippe C.
contents Fiber optic shape sensors have enabled unique advances in various navigation tasks, from medical tool tracking to industrial applications. Eccentric fiber Bragg gratings (FBG) are cheap and easy-to-fabricate shape sensors that are often interrogated with simple setups. However, using low-cost interrogation systems for such intensity-based quasi-distributed sensors introduces further complications to the sensor's signal. Therefore, eccentric FBGs have not been able to accurately estimate complex multi-bend shapes. Here, we present a novel technique to overcome these limitations and provide accurate and precise shape estimation in eccentric FBG sensors. We investigate the most important bending-induced effects in curved optical fibers that are usually eliminated in intensity-based fiber sensors. These effects contain shape deformation information with a higher spatial resolution that we are now able to extract using deep learning techniques. We design a deep learning model based on a convolutional neural network that is trained to predict shapes given the sensor's spectra. We also provide a visual explanation, highlighting wavelength elements whose intensities are more relevant in making shape predictions. These findings imply that deep learning techniques benefit from the bending-induced effects that impact the desired signal in a complex manner. This is the first step toward cheap yet accurate fiber shape sensing solutions.
format Preprint
id arxiv_https___arxiv_org_abs_2210_16316
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle The secret role of undesired physical effects in accurate shape sensing with eccentric FBGs
Roodsari, Samaneh Manavi
Freund, Sara
Angelmahr, Martin
Rauter, Georg
Schade, Wolfgang
Cattin, Philippe C.
Machine Learning
Applied Physics
Optics
Fiber optic shape sensors have enabled unique advances in various navigation tasks, from medical tool tracking to industrial applications. Eccentric fiber Bragg gratings (FBG) are cheap and easy-to-fabricate shape sensors that are often interrogated with simple setups. However, using low-cost interrogation systems for such intensity-based quasi-distributed sensors introduces further complications to the sensor's signal. Therefore, eccentric FBGs have not been able to accurately estimate complex multi-bend shapes. Here, we present a novel technique to overcome these limitations and provide accurate and precise shape estimation in eccentric FBG sensors. We investigate the most important bending-induced effects in curved optical fibers that are usually eliminated in intensity-based fiber sensors. These effects contain shape deformation information with a higher spatial resolution that we are now able to extract using deep learning techniques. We design a deep learning model based on a convolutional neural network that is trained to predict shapes given the sensor's spectra. We also provide a visual explanation, highlighting wavelength elements whose intensities are more relevant in making shape predictions. These findings imply that deep learning techniques benefit from the bending-induced effects that impact the desired signal in a complex manner. This is the first step toward cheap yet accurate fiber shape sensing solutions.
title The secret role of undesired physical effects in accurate shape sensing with eccentric FBGs
topic Machine Learning
Applied Physics
Optics
url https://arxiv.org/abs/2210.16316