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Extraction of Natural Gas Microleakage Stress Regions Based on Hyperspectral Images of Winter Wheat |
LI Hui1, LIU Xu-sheng2, JIANG Jin-bao3*, CHEN Xu-hui4, ZHANG Shuai5, TANG Ke1, ZHAO Xin-wei1, DU Xing-qiang1, YU LONG Fei-xue1 |
1. China Siwei Surveying and Mapping Technology Co., Ltd., Beijing 100086, China
2. Ordos Institute of Technology, Ordos 017000, China
3. College of Geosciences and Surveying Engineering, China University of Mining and Technology, Beijing 100083, China
4. Satellite Application Center for Ecology and Environment, MEE,Beijing 100094, China
5. China Centre for Resources Satellite Data and Application, Beijing 100094, China
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Abstract Natural gas has gradually occupied an important position in the energy structure. As natural gas pipelines and gas storage are buried underground all year round, oxygen-free corrosion, natural disasters, looseness of injection wells and pipelines, and other factors will lead to gas leakage. So, it is necessary to determine the location of leakage points and make early judgments and warnings before large-scale leakage from underground natural gas storage. This paper collected four periods of hyperspectral image data of winter wheat. It integrated the spatial-temporal-spectral features of hyperspectral data to explore the relationship between the radius and duration of winter wheat stress under natural gas stress, thus indirectly detecting the microleakage point of natural gas. On the one hand, the index CWTmexh(CWTmexh=CW2770/(1-CW487)×CW550), constructed by continuous wavelet transform of the canopy spectra after continuum removal, was used to classify pixels into non-stress and stress with threshold segmentation. On the other hand, PCA features of hyperspectral image data are extracted, and natural gas stress regions are identified with the SVM classifier. Finally, the results of both threshold segmentation and SVM classification are analyzed by mathematical morphology, and the stress area is fitted with a circular curve using the least square to explore the relationship between the stress radius of natural gas leakage and the stress days. The results show that: (1) The CWTmexh index can be applied to imaging hyperspectral data, showing good recognition performance; (2) SVM classifier can recognize winter wheat stress areas based on spectral difference characteristics with good classification accuracy (i.e., the maximum classification accuracy of 99.25% and kappa coefficient is 0.97) and the recognition accuracy increases with the continuation of natural gas stress; (3) There is a strong linear correlation between the radius of the stressed area and the ventilation days of winter wheat. Results of this study showed that it is feasible to indirectly identify natural gas micro-leakage points through hyperspectral remote sensing by monitoring surface vegetation at the canopy and low altitude scales and can predict time-dependent changes associated with underground natural gas micro leakage stress. The results can provide a theoretical basis for monitoring the leakage points of underground natural gas storage by spaceborne hyperspectral remote sensing and provide technical support for future engineering applications.
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Received: 2022-10-19
Accepted: 2023-04-27
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Corresponding Authors:
JIANG Jin-bao
E-mail: jjb@cumtb.edu.cn
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[1] ZHANG Ting-shou(张廷首). Chemical Engineering Design Communications(化工设计通讯), 2020, 46(3): 2.
[2] Tubb Rita. Pipeline and Gas Journal, 2016, 243(1): 238.
[3] CAI Xiao-long, LIU Yong-jun, DONG Xiao-qi(蔡晓龙, 刘永军, 董晓琪). Journal of Oil and Gas Technology(石油天然气学报), 2021, 43(2): 6.
[4] Khanna S, Santos M J, Koltunov A, et al. Remote Sensing, 2017, 9(2): 169.
[5] YOU Jin-feng, XING Li-xin, PAN Jun, et al(尤金凤, 邢立新, 潘 军, 等). Journal of Jilin University: Earth Science Edition(吉林大学学报: 地球科学版), 2016, 46(5): 1589.
[6] Jiang J B, Steven M D, He R Y, et al. International Journal of Greenhouse Gas Control, 2015, 37: 1.
[7] LI Hui, JIANG Jin-bao, CHEN Xu-hui, et al(李 辉, 蒋金豹, 陈绪慧). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2019, 39(12): 3743.
[8] van der Werff H M A, Bakker W H, van der Meer F D, et al. Computers & Geosciences, 2006, 32(5): 1334.
[9] Sanches I D, Filho C R S, Kokaly R F. ISPRS Journal of Photogrammetry and Remote Sensing, 2014, 97: 111.
[10] TONG Qing-xi, ZHANG Bing, ZHENG Lan-fen(童庆喜, 张 兵, 郑兰芬). Hyperspectral Remote Sensing: Principle, Technology and Applications(高光谱遥感:原理技术与应用). Beijing: Higher Education Press(北京:高等教育出版社), 2006.
[11] CUI Xin, ZHAO Ying-jun, TIAN Feng, et al(崔 鑫, 赵英俊, 田 丰, 等). Acta Geologica Sinica(地质学报), 2019,93(4): 928.
[12] Noomen Marleen F, Skidmore Andrew K, van der Meer Freek D, et al. Remote Sensing of Environment, 2006, 105(3): 262.
[13] van der Werff Harald, van der Meijde Mark, Jansma Fokke, et al. Sensors, 2008, 8(6): 3733.
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