师资力量：中山大学测绘科学与技术学院老师王天星简介

[1]  Wang,T., Shi,J., Ma, Y., Letu, H., & Li, X. (2020). All-sky longwave downward radiationfrom satellite measurements: General parameterizations based on LST, columnwater vapor and cloud top temperature. ISPRSJournal of Photogrammetry and Remote Sensing, 161, 52-60.

[2]  Wang, T., Shi, J., Ma, Y.,Husi, L., Comyn‐Platt, E., Ji, D & Xiong, C. (2019). Recovering landsurface temperature under cloudy skies considering the solar‐cloud‐satellitegeometry: application to MODIS and Landsat‐8 data. Journal of GeophysicalResearch: Atmospheres,124(6), 3401-3416.

[3]  Wang, T., Shi, J., Letu, H.,Ma, Y., Li, X., & Zheng, Y. (2019). Detection and removal of clouds andassociated shadows in satellite imagery based on simulated radiance fields. Journalof Geophysical Research: Atmospheres, 124. 7207-7225.

[4]  Zhou, W., Shi, J., Wang, T.*, Peng,B., Husi, L., Yu, Y. C.,& Zhao, R. (2019).New methods for deriving clear‐sky surface longwavedownward radiation based on remotely sensed data and ground measurements.Earth and Space Science, 6(11),2071-2086.

[5]  Yu, Y., Shi, J., Wang, T. *, Letu, H., Yuan, P., Zhou, W.,& Hu, L. (2019). Evaluation of the Himawari-8 Shortwave Downward Radiation(SWDR) Product and its Comparison With the CERES-SYN, MERRA-2, and ERA-InterimDatasets. IEEE Journal of Selected Topics in Applied Earth Observations andRemote Sensing,12 (2), 519-532.

[6]  Wang, T., Shi, J., Yu, Y.,Husi, L., Gao, B., Zhou, W. & Chen, L. (2018). Cloudy-sky land surfacelongwave downward radiation (LWDR) estimation by integrating MODIS andAIRS/AMSU measurements.Remote Sensing of Environment, 205, 100-111.

[7]  Wang, T., Yan, G., Mu, X.,Jiao, Z., Chen, L., & Chu, Q. (2018). Toward operational
shortwave radiation modeling and retrieval over rugged terrain.RemoteSensing of Environment,205, 419-433.

[8]Zhou, W., Shi, J., Wang, T.*, Peng, B., Zhao, R., & Yu,Y. (2018). Clear-Sky Longwave Downward Radiation Estimation by IntegratingMODIS Data and Ground-Based Measurements. IEEE Journal of Selected Topics inApplied Earth Observations and Remote Sensing, 12(2), 450-459.

[9]Jing, Y., Wang, T.*, Zhang, P., Chen, L., Xu, N., & Ma,Y. (2018). Global Atmospheric CO2 Concentrations Simulated by GEOS-Chem:Comparison with GOSAT, Carbon Tracker and Ground-Based Measurements. Atmosphere,9(5),175.

[10] Wang, T, Shi, J., Husi, L., Zhao, T., Ji, D., Xiong, C., & Gao, B.(2017). Effect of Solar-Cloud-Satellite Geometry on Land Surface ShortwaveRadiation Derived from Remotely Sensed Data. Remote Sensing, 9(7), 690.

[11] Yan, G, Wang, T*,Jiao, Z., Mu, X., Zhao, J., & Chen, L. (2016). Topographic radiationmodeling and spatial scaling of clear-sky land surface longwave radiation overrugged terrain. Remote Sensing of Environment, 172, 15-27.

[12] Liu, Y., Wang,T.*, Ma, L., & Wang, N. (2014). Spectral calibration of hyperspectraldata observed from a hyperspectrometer loaded on an unmanned aerial vehicleplatform. IEEE Journal of Selected Topics in Applied Earth Observations andRemote Sensing, 7(6), 2630-2638.

[13] Wang T., J. Shi,Y. Jing,Y. Xie. Investigation of the consistency ofatmospheric CO2 retrievals from different space-based sensors: Intercomparisonand spatio-temporal analysis, Chinese Science Bulletin, 2013, 58(33):4161-4170.

[14] Wang T., Yan G, Ling Chen. Consistent retrieval methods to estimate landsurface shortwave and longwave radiative flux components under clear skyconditions, Remote Sensing of Environment, 2012, 124, 61-71.

[15] Wang T, Yan G, Huazhong Ren, Xiha Mu. Improved Methods for SpectralCalibration of On-orbit Imaging Spectrometers. IEEE Transactions onGeoscience and Remote Sensing, 2010, 48(11): 3924-3931.