Repetition Rate and Gauge Length Impact on DTGS Temperature Reconstruction

Danilo Fernandes Gomes; Guilherme Heim Weber; Eduardo Henrique Dureck; Daniel Rodrigues Pipa; Marco Da Silva; Jean Carlos Cardozo da Silva; Sérgio Taveira de Camargo Júnior; Manoel Feliciano da Silva; Cicero Martelli

doi:10.1109/LSENS.2023.3307056

Repetition Rate and Gauge Length Impact on DTGS Temperature Reconstruction

Danilo Fernandes Gomes
, Guilherme Heim Weber
, Eduardo Henrique Dureck
, Daniel Rodrigues Pipa
, Marco Da Silva
, Jean Carlos Cardozo da Silva
, Sérgio Taveira de Camargo Júnior
, Manoel Feliciano da Silva
, Cicero Martelli

Institute of Measurement Technology

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

Abstract

Distributed temperature gradient sensing (DTGS) systems have found widespread applications, particularly in the oil and gas industry. These systems use the analysis of phase variations in backscattered light from optical fibers to provide valuable information about temperature distributions. Thus, obtaining an accurate reconstruction of the phase variations of the backscattered light is essential to achieve reliable and accurate measurements of the thermal gradient. This letter addresses the limitations of the phase unwrapping algorithm in DTGS applications and proposes an evaluation of the impact of repetition rate and gauge length on the reconstruction of the distributed temperature. Through experimental tests and theoretical analyses, limiting parameters for data acquisition and those can compromise measurement accuracy are investigated. The findings contribute to improving the use of DTGS systems, allowing more accurate and reliable temperature monitoring in distributed systems.

Original language	English
Article number	5001104
Number of pages	4
Journal	IEEE Sensors Letters
Volume	7
Issue number	9
DOIs	https://doi.org/10.1109/LSENS.2023.3307056
Publication status	Published - 01 Sept 2023

Fields of science

202012 Electrical measurement technology
202014 Electromagnetism
202021 Industrial electronics
202024 Laser technology
202036 Sensor systems
211908 Energy research
101014 Numerical mathematics
102003 Image processing
202 Electrical Engineering, Electronics, Information Engineering
202015 Electronics
202016 Electrical engineering
202022 Information technology
202027 Mechatronics
202037 Signal processing
202039 Theoretical electrical engineering
203016 Measurement engineering
103021 Optics

JKU Focus areas

Digital Transformation

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10.1109/LSENS.2023.3307056

Cite this

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title = "Repetition Rate and Gauge Length Impact on DTGS Temperature Reconstruction",

abstract = "Distributed temperature gradient sensing (DTGS) systems have found widespread applications, particularly in the oil and gas industry. These systems use the analysis of phase variations in backscattered light from optical fibers to provide valuable information about temperature distributions. Thus, obtaining an accurate reconstruction of the phase variations of the backscattered light is essential to achieve reliable and accurate measurements of the thermal gradient. This letter addresses the limitations of the phase unwrapping algorithm in DTGS applications and proposes an evaluation of the impact of repetition rate and gauge length on the reconstruction of the distributed temperature. Through experimental tests and theoretical analyses, limiting parameters for data acquisition and those can compromise measurement accuracy are investigated. The findings contribute to improving the use of DTGS systems, allowing more accurate and reliable temperature monitoring in distributed systems.",

author = "\{Fernandes Gomes\}, Danilo and \{Heim Weber\}, Guilherme and \{Henrique Dureck\}, Eduardo and \{Rodrigues Pipa\}, Daniel and \{Da Silva\}, Marco and \{da Silva\}, \{Jean Carlos Cardozo\} and \{de Camargo J{\'u}nior\}, \{S{\'e}rgio Taveira\} and \{da Silva\}, \{Manoel Feliciano\} and Cicero Martelli",

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doi = "10.1109/LSENS.2023.3307056",

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T1 - Repetition Rate and Gauge Length Impact on DTGS Temperature Reconstruction

AU - Fernandes Gomes, Danilo

AU - Heim Weber, Guilherme

AU - Henrique Dureck, Eduardo

AU - Rodrigues Pipa, Daniel

AU - Da Silva, Marco

AU - da Silva, Jean Carlos Cardozo

AU - de Camargo Júnior, Sérgio Taveira

AU - da Silva, Manoel Feliciano

AU - Martelli, Cicero

PY - 2023/9/1

Y1 - 2023/9/1

N2 - Distributed temperature gradient sensing (DTGS) systems have found widespread applications, particularly in the oil and gas industry. These systems use the analysis of phase variations in backscattered light from optical fibers to provide valuable information about temperature distributions. Thus, obtaining an accurate reconstruction of the phase variations of the backscattered light is essential to achieve reliable and accurate measurements of the thermal gradient. This letter addresses the limitations of the phase unwrapping algorithm in DTGS applications and proposes an evaluation of the impact of repetition rate and gauge length on the reconstruction of the distributed temperature. Through experimental tests and theoretical analyses, limiting parameters for data acquisition and those can compromise measurement accuracy are investigated. The findings contribute to improving the use of DTGS systems, allowing more accurate and reliable temperature monitoring in distributed systems.

AB - Distributed temperature gradient sensing (DTGS) systems have found widespread applications, particularly in the oil and gas industry. These systems use the analysis of phase variations in backscattered light from optical fibers to provide valuable information about temperature distributions. Thus, obtaining an accurate reconstruction of the phase variations of the backscattered light is essential to achieve reliable and accurate measurements of the thermal gradient. This letter addresses the limitations of the phase unwrapping algorithm in DTGS applications and proposes an evaluation of the impact of repetition rate and gauge length on the reconstruction of the distributed temperature. Through experimental tests and theoretical analyses, limiting parameters for data acquisition and those can compromise measurement accuracy are investigated. The findings contribute to improving the use of DTGS systems, allowing more accurate and reliable temperature monitoring in distributed systems.

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UR - https://www.scopus.com/pages/publications/85168741354

U2 - 10.1109/LSENS.2023.3307056

DO - 10.1109/LSENS.2023.3307056

M3 - Article

SN - 2475-1472

VL - 7

JO - IEEE Sensors Letters

JF - IEEE Sensors Letters

IS - 9

M1 - 5001104

ER -

Repetition Rate and Gauge Length Impact on DTGS Temperature Reconstruction

Abstract

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