Simulation evaluation of a single-photon laser methane remote sensor for leakage rate monitoring

doi:10.1364/OE.513894

	Simulation evaluation of a single-photon laser methane remote sensor for leakage rate monitoring
	Zhu, Shouzheng 1,2; Liu, Shijie 1; Tang, Guoliang 1; He, Xin 1; Zhou, Hao 1; Wang, Senyuan 3; Yang, Shicheng4 ; Huang, Pujiang 1,2; Yang, Wenhang 1,2; Zhao, Bangjian 1; Li, Chunlai 1,3; Wang, Jianyu 1,3
	2024-03-25
发表期刊	OPTICS EXPRESS (IF:3.2[JCR-2023],3.4[5-Year])
ISSN	1094-4087
EISSN	1094-4087
卷号	32 期号:7 页码:10962-10978
发表状态	已发表
DOI	10.1364/OE.513894
摘要	We propose a novel methane leakage rate remote sensor that combines a single-photon avalanche diode detector with a near-infrared 1653.7 nm low-power laser. The proposed M sequence and triangle wave signal modulation method simultaneously realizes the detection of methane leakage and target point clouds. Innovatively, the sensor's methane concentration and leakage rate quantification ability were simulated by combining the Gaussian plume diffusion model and the Risley prism. The effects of the prism rotation ratio, wind speed, leakage rate, atmospheric stability (AS), target reflectivity, signal averaging period, and concentration spatial interpolation method on leakage rate are discussed. When plume methane concentrations reduce from 10, 000 to 500 ppm·m, the relative concentration bias rise from 1% to 30%, the absolute concentration bias is approximately 100 ppm·m. Two spatial concentration interpolation methods introduced leakage rate bias ranging from 6%-25%. For a low AS, the leakage rate bias under the cubic interpolation method was small (approximately 1.6%). In addition, when the initial leakage rate increased from 100 to 1, 000 mg/s, the leakage rate bias was approximately 20% smaller. © 2024 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement.
关键词	Avalanche diodes Infrared devices Interpolation Optical radar Particle beams Photons Prisms Remote sensing Wind Atmospheric stability Leakage rates Methane concentrations Methane leakage Photon lasers Rate monitoring Remote sensors Simulation evaluation Single photon avalanche diode Single photons
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收录类别	EI ; SCI
语种	英语
资助项目	National Defense Pre-Research Foundation of China[D040107] ; The 173 Key Projects of Basic Research[2021-JCJO-ZD-025-11] ; High Resolution Imaging Spectrometer (HRIS) technology and equipment[2023C03012] ; Development of a high-precision CO2 online analyzer based on cavity-enhanced absorption spectroscopy[B02006C019019] ; Research on active detection technology of extreme sensitivity gas based on mid-infrared band[B02006C019001]
WOS研究方向	Optics
WOS类目	Optics
WOS记录号	WOS:001207090500006
出版者	Optica Publishing Group (formerly OSA)
EI入藏号	20241415838592
EI主题词	Methane
EI分类号	443.1 Atmospheric Properties ; 714.1 Electron Tubes ; 716.2 Radar Systems and Equipment ; 741.3 Optical Devices and Systems ; 804.1 Organic Compounds ; 921.6 Numerical Methods ; 931.3 Atomic and Molecular Physics ; 932.1 High Energy Physics
原始文献类型	Journal article (JA)
引用统计	正在获取...
文献类型	期刊论文
条目标识符	https://kms.shanghaitech.edu.cn/handle/2MSLDSTB/359878
专题	信息科学与技术学院信息科学与技术学院_硕士生
作者单位	1.Hangzhou Institute for Advanced Study, University of Chinese Academy of Sciences, Zhejiang, Hangzhou; 310024, China; 2.University of Chinese Academy of Sciences, Beijing; 100049, China; 3.Shanghai Institute of Technical Physics, Chinese Academy of Sciences, Shanghai; 200083, China; 4.School of Information Science and Technology, Shanghai Tech University, Shanghai; 201210, China
推荐引用方式 GB/T 7714	Zhu, Shouzheng,Liu, Shijie,Tang, Guoliang,et al. Simulation evaluation of a single-photon laser methane remote sensor for leakage rate monitoring[J]. OPTICS EXPRESS,2024,32(7):10962-10978.
APA	Zhu, Shouzheng.,Liu, Shijie.,Tang, Guoliang.,He, Xin.,Zhou, Hao.,...&Wang, Jianyu.(2024).Simulation evaluation of a single-photon laser methane remote sensor for leakage rate monitoring.OPTICS EXPRESS,32(7),10962-10978.
MLA	Zhu, Shouzheng,et al."Simulation evaluation of a single-photon laser methane remote sensor for leakage rate monitoring".OPTICS EXPRESS 32.7(2024):10962-10978.