TY - GEN
T1 - MWIRGas-YOWO
T2 - 5th IEEE International Conference on Computer Communication and Artificial Intelligence, CCAI 2025
AU - Wang, Lingzhi
AU - Yang, Hongjie
AU - Long, Ying
AU - Liu, Enjin
AU - Gao, Xiang
AU - Liu, Renxi
AU - Wang, Shan
AU - Pan, Feng
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - In industrial production, most potential safety hazards originate from the leakage of combustible gases. Many combustible gases are indistinguishable to the naked eye, and gases have no fixed shape, low contrast, and are colorless. Aiming at the detection difficulties of gases in industrial gas leakage detection, this paper proposes a spatio-temporal fusion detection algorithm MWIRGas-YOWO based on the improved YOWOv2 framework. By establishing a self-built medium-wave infrared dataset in multiple scenarios, it covers gas leakage scenarios under environmental conditions such as different concentrations and different gas pressures in the 3.2-3.4 μ m band. Firstly, the input module in the MWIRGas-YOWO network is adjusted to be adapted to the infrared images directly collected by the mediumwave cooled infrared thermal imager. Next, in view of the characteristics of gases having no fixed shape and undergoing diffusive motion, YOWO is transferred to the task of infrared gas detection. Then, by combining the 3D-2D dual-stream feature extraction with the dynamic label assignment strategy, the balance between accuracy and speed is achieved. Finally, the image data of gas leakage in industrial scenarios are actually collected for model training and evaluation comparison. Experiments show that the accuracy rates of the improved model on two videos actually collected at industrial sites reach 78% and 74%, which is significantly improved compared with mainstream algorithms. This study provides a highly reliable solution for gas detection in industrial production.
AB - In industrial production, most potential safety hazards originate from the leakage of combustible gases. Many combustible gases are indistinguishable to the naked eye, and gases have no fixed shape, low contrast, and are colorless. Aiming at the detection difficulties of gases in industrial gas leakage detection, this paper proposes a spatio-temporal fusion detection algorithm MWIRGas-YOWO based on the improved YOWOv2 framework. By establishing a self-built medium-wave infrared dataset in multiple scenarios, it covers gas leakage scenarios under environmental conditions such as different concentrations and different gas pressures in the 3.2-3.4 μ m band. Firstly, the input module in the MWIRGas-YOWO network is adjusted to be adapted to the infrared images directly collected by the mediumwave cooled infrared thermal imager. Next, in view of the characteristics of gases having no fixed shape and undergoing diffusive motion, YOWO is transferred to the task of infrared gas detection. Then, by combining the 3D-2D dual-stream feature extraction with the dynamic label assignment strategy, the balance between accuracy and speed is achieved. Finally, the image data of gas leakage in industrial scenarios are actually collected for model training and evaluation comparison. Experiments show that the accuracy rates of the improved model on two videos actually collected at industrial sites reach 78% and 74%, which is significantly improved compared with mainstream algorithms. This study provides a highly reliable solution for gas detection in industrial production.
KW - Detection accuracy and speed
KW - Industrial gas leakage detection
KW - Mid-wave infrared
KW - Spatio-temporal fusion
UR - https://www.scopus.com/pages/publications/105020962344
U2 - 10.1109/CCAI65422.2025.11189522
DO - 10.1109/CCAI65422.2025.11189522
M3 - Conference contribution
AN - SCOPUS:105020962344
T3 - 2025 IEEE 5th International Conference on Computer Communication and Artificial Intelligence, CCAI 2025
SP - 148
EP - 153
BT - 2025 IEEE 5th International Conference on Computer Communication and Artificial Intelligence, CCAI 2025
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 23 May 2025 through 25 May 2025
ER -