Abstract
Natural gas leakage occurs frequently due to aging pipes and other factors, but is challenging to detect. In this article, a new, robust method for nondestructive natural gas microleakage detection was proposed. It combines a crop growth model with a convolutional neural network (CNN) approach to quantitatively detect underground natural gas leakage using unmanned aerial vehicle (UAV) hyperspectral imagery. The environmental stress on wheat was used as an indicator to reflect the intensity of natural gas leakage. First, a crop growth model (simple algorithm for yield, SAFY) was used to simulate the growth of wheat, and the environmental stress factor in the model was used to construct the natural gas stress index (<i>K</i><sub>gs</sub>). Subsequently, CNN models were used to estimate the <i>K</i><sub>gs</sub> value with a hyperspectral image as the input. Finally, the CNN estimated <i>K</i><sub>gs</sub> was used to detect the natural gas leakage in the study area. Results showed that the SAFY model <i>K</i><sub>gs</sub> value could effectively identify natural gas leakage, with statistically significant differences (<i>p</i>-value < 0.05) among three leakage levels. Furthermore, compared to a single spectral index, <i>K</i><sub>gs</sub> had superior robustness throughout the wheat growth period. The CNN-1D model with InceptionV2 architecture exhibited the best accuracy in estimating <i>K</i><sub>gs</sub>, with a robust nRMSE of 6.9%. Overall, the combined CNN and SAFY models could accurately detect natural gas leakage, and this approach is more robust than traditional spectral index-based methods. This article provides a new method for nondestructive detecting of natural gas microleakage.
Highlights
NATURAL gas is a safe, environmentally friendly, and. high-quality energy source, and occupies an important market position
A major reason may be that Pla and Plb had a smaller parameter adjustment range compared to senescence accumulated temperature threshold (STT) and Rs
For the V1 cultivar, when the natural gas leakage rate increased from G1 (1 L·min-1) to G2 (1.5 L·min-1), the decrease in the leaf area index (LAI) peak was approximately 0.2 for the central and edge area samples, respectively
Summary
NATURAL gas is a safe, environmentally friendly, and. high-quality energy source, and occupies an important market position. Pipelines are common methods of transport and underground storage is widespread [1]. Both are susceptible to damage from natural or human factors, and the resulting gas leakage can be hazardous and result in economic losses [2]. It is important to detect natural gas leakage in a timely and accurate manner. Manual methods of underground gas leakage detection are time-consuming and struggle to detect micro-leakage. Underground gas leakage decrease soil oxygen content, thereby inhibiting aerobic respiration in plant root cells and negatively impacting plant health [4]. The extent of an underground natural gas leakage can be monitored indirectly by examining crop growth
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
