TY - GEN
T1 - The Analysis of Hydrogen and Nitrogen Mediums for VLC-Based Downhole Gas Pipe Monitoring System
AU - Alaca, Ozgur
AU - Tokgoz, Sezer C.
AU - Retnanto, Albertus
AU - Miller, Scott L.
AU - Qaraqe, Khalid A.
N1 - Publisher Copyright:
© 2023 IEEE.
PY - 2023
Y1 - 2023
N2 - Downhole gas pipe monitoring systems have an essential role in the extraction and monitoring processes of oil and gas. Since the most critical part of these systems is real-time data transmission, a novel transmission system is required to meet increasing bandwidth and capacity prerequisites. Therefore, visible light communication (VLC) becomes a significant emerging technology for downhole gas pipe monitoring systems in terms of high bandwidth and data rate. Following this direction, the VLC-based downhole gas pipe monitoring system is investigated by considering different modulation schemes and mediums. Specifically, a carbon steel-coated gas pipe channel is established with a transmitting light source and a photodetector to simulate the real field conditions of the VLC-based gas pipe monitoring system. Also, the well-known ACO-OFDM and OKK modulation schemes are employed and compared under real-world conditions. On the other hand, this study investigates for the first time the use of hydrogen gas medium, which is commonly employed to make lighter products from heavy petroleum fractions. Then, based on practical considerations, the performance of the VLC-based system is analyzed under different gases including nitrogen and hydrogen. Hence, for the performance metric, the bit-error rate is utilized and presented by considering the impact of internal pipe pressure and the circulating pump. As for the channel characterization of the hydrogen and nitrogen mediums, the channel impulse response is obtained and used to calculate the channel DC gain and path loss. Results demonstrate that the proposed VLC-based system achieves significant performance and is slightly affected by channel modifications.
AB - Downhole gas pipe monitoring systems have an essential role in the extraction and monitoring processes of oil and gas. Since the most critical part of these systems is real-time data transmission, a novel transmission system is required to meet increasing bandwidth and capacity prerequisites. Therefore, visible light communication (VLC) becomes a significant emerging technology for downhole gas pipe monitoring systems in terms of high bandwidth and data rate. Following this direction, the VLC-based downhole gas pipe monitoring system is investigated by considering different modulation schemes and mediums. Specifically, a carbon steel-coated gas pipe channel is established with a transmitting light source and a photodetector to simulate the real field conditions of the VLC-based gas pipe monitoring system. Also, the well-known ACO-OFDM and OKK modulation schemes are employed and compared under real-world conditions. On the other hand, this study investigates for the first time the use of hydrogen gas medium, which is commonly employed to make lighter products from heavy petroleum fractions. Then, based on practical considerations, the performance of the VLC-based system is analyzed under different gases including nitrogen and hydrogen. Hence, for the performance metric, the bit-error rate is utilized and presented by considering the impact of internal pipe pressure and the circulating pump. As for the channel characterization of the hydrogen and nitrogen mediums, the channel impulse response is obtained and used to calculate the channel DC gain and path loss. Results demonstrate that the proposed VLC-based system achieves significant performance and is slightly affected by channel modifications.
KW - ACO-OFDM
KW - Downhole gas pipe monitoring system
KW - OOK
KW - visible light communications
UR - http://www.scopus.com/inward/record.url?scp=85178996713&partnerID=8YFLogxK
U2 - 10.1109/BlackSeaCom58138.2023.10299758
DO - 10.1109/BlackSeaCom58138.2023.10299758
M3 - Conference contribution
AN - SCOPUS:85178996713
T3 - 2023 IEEE International Black Sea Conference on Communications and Networking, BlackSeaCom 2023
SP - 76
EP - 81
BT - 2023 IEEE International Black Sea Conference on Communications and Networking, BlackSeaCom 2023
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2023 IEEE International Black Sea Conference on Communications and Networking, BlackSeaCom 2023
Y2 - 4 July 2023 through 7 July 2023
ER -