[1] Qian YANG, Li GUAN, Fa TAO et al. Changing patterns of CH4 concentration observed at five atmospheric background stations in China. Environmental Science and Technology, 41, 1-7(2018).

[2] M A K KHALIL, R A RASMUSSEN. Atmospheric methane： Trends over the last 10 000 years. Atmospheric Environment, 21, 2445-2452(1987).

[3] Xingying ZHANG, Wenguang BAI, Peng ZHANG et al. Satellite remote sensing of the temporal and spatial distribution characteristics of atmospheric methane in the middle and upper troposphere in China. Scientific Bulletin, 56, 2804-2811(2011).

[4] E G NISBET, E J DLUGOKENCKY, P BOUSQUET. Methane on the Rise—Again. Science, 343, 493-495(2014).

[5] Jiashan ZHU, Ming WEI. Study on the mechanism of methane column change affecting atmospheric structure and local heavy precipitation. Remote Sensing Technology and Application, 33, 449-457(2018).

[6] Haibao WU. Photochemical reaction of methane in the atmosphere and its environmental effects. Environmental Pollution and Prevention, 13-15(1989).

[7] Shuanghui LIU, Xiaoying LI, Xifeng CAO et al. Advances in atmospheric methane detection and global methane distribution analysis. Remote Sensing Technology and Application, 37, 436-450(2022).

[8] Guojun ZHANG, Qun LE. Spatial and temporal distribution of CH4 column concentration in China based on SCIAMACHY WFM-DOAS data, 2010, 5.

[9] A LORENTE, T BORSDORFF, A BUTZ et al. Methane retrieved from TROPOMI： Improvement of the data product and validation of the first 2 years of measurements. Atmospheric Measurement Techniques, 14, 665-684(2021).

[10] Aijun ZHU, Xiuqing HU, Manyun LIN et al. Global data acquisition method and data distribution of Fengyun-3 D meteorological satellite. Journal of Marine Meteorology, 38, 1-10(2018).

[11] Hailiang SHI, Wei XIONG, Zhiwei LI et al. Quality analysis of on-orbit observation data of atmospheric main greenhouse gas monitors. Shanghai Aerospace, 161-166(2019).

[12] X XIONG, C BARNET, E MADDY et al. Characterization and validation of methane products from the Atmospheric Infrared Sounder（AIRS）. Journal of Geophysical Research, 113, G00-01(2008).

[13] C CREVOISIER, D NOBILEAU, A M FIORE et al. Tropospheric methane in the tropics–first year from IASI hyperspectral infrared observations. Atmospheric Chemistry and Physics, 9, 6337-6350(2009).

[14] A BUTZ, S GUERLET, O HASEKAMP et al. Toward accurate CO2 and CH4 observations from GOSAT： GOSAT CO2 AND CH4 VALIDATION. Geophysical Research Letters, 38(2011).

[15] C CRESSOT, F CHEVALLIER, P BOUSQUET et al. On the consistency between global and regional methane emissions inferred from SCIAMACHY，TANSO-FTS，IASI and surface measurements. Atmospheric Chemistry and Physics, 14, 577-592(2014).

[16] Pengfei MA, Liangfu CHEN, Jinhua TAO et al. Simulation study on the inversion of atmospheric temperature and humidity profiles using infrared hyperspectral data CrIS. Spectroscopy and Spectral Analysis, 34, 1894-1897(2014).

[17] Yi LIAO, Li GUAN. Precision evaluation of spectral data of FY-3E infrared hyperspectral atmospheric detector. Geophysical Progress, 38, 977-986(2023).

[18] Pengfei ZHANG, Li YANG, Yifei FU. Successful launch of Fengyun-3F Star. Science and Technology Daily.

[19] Haiping WANG, Yi LIU, Zhaonan CAI. Application of MIPAS / ENVISAT satellite remote sensing data to study the characteristics of atmospheric chemical composition changes during stratospheric explosive warming. Remote sensing technology and application, 102, 389-393，359(2008).

[20] Xiaoli WU, Dongdong FAN, Ping WANG. Fourier transform infrared spectrometer for atmospheric composition detection in space. Space Return and Remote Sensing, 2007, 15-20，28.

[21] Jing MIAO, Xiaoying LI, Hongmei WANG, et al. GF-5 AIUS water vapor profile inversion algorithm research. Journal of Remote Sensing, 25, 1201-1215(2021).

[22] Z G YAO, J HONG, X D CUI et al. A Neural network based single footprint temperature retrieval for atmospheric infrared sounder measurements and its application to study on stratospheric gravity wave. Journal of Tropical Meteorology, 28, 82-94(2022).

[23] X LI, J XU, T CHENG et al. Monitoring trace gases over the antarctic using atmospheric infrared ultraspectral sounder onboard GaoFen-5： Algorithm Description and first retrieval results of O3，H2O，and HCl. Remote Sensing, 11(2019).

[24] X CAO, X LI, S LIU et al. Assessment of spectra of the atmospheric infrared ultraspectral sounder on GF-5 and validation of water vapor retrieval. Sensors, 21(2021).

[25] Shuiping ZHANG. Channel selection for retrieving atmospheric temperature profiles from AIRS data. Meteorology, 29, 4475-4481(2009).

[26] C D Rodgers. Information content and optimization of highspectral-resolution measurements, 136-147(1996).

[27] F Rabier, N Fourrié, D Chafäi et al. Channel selection methods for infrared atmospheric sounding interferometer radiances. Quarterly Journal of the Royal Meteorological Society, 128, 1011-1027(2002).

[28] Y C NOH, B J SOHN, Y KIM et al. A new Infrared Atmospheric Sounding Interferometer channel selection and assessment of its impact on Met Office NWP forecasts. Advances in Atmospheric Sciences, 34, 1265-1281(2017).

[29] Huadong DU, Sixun HUANG, Hanqing SHI. Optimal channel selection method and experiment for high spectral resolution remote sensing data. According to Chinese Journal of Physics, 57, 7685-7692(2008).

[30] D DI, J LI, W HAN et al. Geostationary hyperspectral infrared sounder channel selection for capturing Fast-Changing atmospheric information. IEEE Transactions on Geoscience and Remote Sensing, 60, 1-10(2022).

[31] Tianhang YANG, Chunming ZHANG, Fenghua ZUO et al. Cross-calibration matching uncertainty analysis based on FY-3E satellite-based infrared observation. Infrared and Laser Engineering：, 52, 17-20(2023).

[32] Y GUO, X LI, T CHENG et al. Construction of the Global Reference Atmospheric Profile Database. Remote Sensing, 15, 3006(2023).

[33] Shulei LI, Lei LIU, Taichang GAO. Introduction of Atmos-pheric Radiative Transfer Simulator（ARTS） software. Journal of Atmospheric and Environmental Optics, 11, 241-248(2016).

[34] Xialin MA, Fengying ZHANG. Preliminary experiments on the inversion of total ozone content with satellite data. Atmospheric Science, 10, 383-391(1986).

[35] Luhan Li. Evaluation and quality control of typhoon numerical simulation based on Himawari-8 all-sky infrared radiation(2018).

[36] P Edwards David. Genln2： A general line-by-line atmospherictransmittance and radiance model， version 3.0 description and usersguide(1992).

[37] A DUDHIA. The Reference Forward Model （RFM）. Journal of Quantitative Spectroscopy and Radiative Transfer, 186, 243-253(2017).

[38] Xifeng CAO, Xiaoying LI. Selection of AIUS temperature inver-sion channel for Gaofen-5. Journal of Remote Sensing, 24, 1157-1167(2020).

[39] Congming DAI, Reasonable WEI, Shunxing Hu. Characterization of the effect of different versions of HITRAN database on radiative transfer in the upper atmosphere. Journal of Optics, 33, 9-16(2013).

[40] L S ROTHMAN, D JACQUEMART, A BARBE et al. The HITRAN 2004 molecular spectroscopic database. Journal of Quantitative Spectroscopy & Radiative Transfer, 96, 139-204(2005).