22.1.5.34 Surface Temperature, Atmospheric Measurements, Remote Sensing

Hu, T., Cao, B., Du, Y., Li, H., Wang, C., Bian, Z., Sun, D., Liu, Q.,
Estimation of Surface Upward Longwave Radiation Using a Direct Physical Algorithm,
GeoRS(55), No. 8, August 2017, pp. 4412-4426.
IEEE DOI 1708
Anisotropic magnetoresistance, Atmospheric modeling, Earth, Estimation, Land surface, Land surface temperature, Remote sensing, Band conversion, combined algorithm, direct physical algorithm, kernel-driven model, surface upward longwave radiation (SULR), thermal, anisotropy BibRef

Geletic, J.[Jan], Lehnert, M.[Michal], Dobrovolný, P.[Petr],
Land Surface Temperature Differences within Local Climate Zones, Based on Two Central European Cities,
RS(8), No. 10, 2016, pp. 788.
DOI Link 1609
BibRef

Chang, R.[Rui], Zhu, R.[Rong], Guo, P.[Peng],
A Case Study of Land-Surface-Temperature Impact from Large-Scale Deployment of Wind Farms in China from Guazhou,
RS(8), No. 10, 2016, pp. 790.
DOI Link 1609
BibRef

Martins, J.P.A.[João P. A.], Trigo, I.F.[Isabel F.], Bento, V.A.[Virgílio A.], da Camara, C.[Carlos],
A Physically Constrained Calibration Database for Land Surface Temperature Using Infrared Retrieval Algorithms,
RS(8), No. 10, 2016, pp. 808.
DOI Link 1609
BibRef

Simó, G.[Gemma], García-Santos, V.[Vicente], Jiménez, M.A.[Maria A.], Martínez-Villagrasa, D.[Daniel], Picos, R.[Rodrigo], Caselles, V.[Vicente], Cuxart, J.[Joan],
Landsat and Local Land Surface Temperatures in a Heterogeneous Terrain Compared to MODIS Values,
RS(8), No. 10, 2016, pp. 849.
DOI Link 1609
BibRef

Mandanici, E.[Emanuele], Conte, P.[Paolo], Girelli, V.A.[Valentina A.],
Integration of Aerial Thermal Imagery, LiDAR Data and Ground Surveys for Surface Temperature Mapping in Urban Environments,
RS(8), No. 10, 2016, pp. 880.
DOI Link 1609
BibRef

Song, K.S.[Kai-Shan], Wang, M.[Min], Du, J.[Jia], Yuan, Y.[Yue], Ma, J.H.[Jian-Hang], Wang, M.[Ming], Mu, G.Y.[Guang-Yi],
Spatiotemporal Variations of Lake Surface Temperature across the Tibetan Plateau Using MODIS LST Product,
RS(8), No. 10, 2016, pp. 854.
DOI Link 1609
BibRef

Li, Y., Lin, X., Song, S., Yang, Y., Cheng, X., Chen, Z., Liu, L., Xia, Y., Xiong, J., Gong, S., Li, F.,
A Combined Rotational Raman-Rayleigh Lidar for Atmospheric Temperature Measurements Over 5X80 km With Self-Calibration,
GeoRS(54), No. 12, December 2016, pp. 7055-7065.
IEEE DOI 1612
BibRef
And: Corrections: GeoRS(55), No. 2, February 2017, pp. 1222-1222.
IEEE DOI 1702
Atmospheric measurements. atmospheric temperature BibRef

Zhou, J.[Ji], Liu, S.M.[Shao-Min], Li, M.S.[Ming-Song], Zhan, W.F.[Wen-Feng], Xu, Z.[Ziwei], Xu, T.[Tongren],
Quantification of the Scale Effect in Downscaling Remotely Sensed Land Surface Temperature,
RS(8), No. 12, 2016, pp. 975.
DOI Link 1612
BibRef

Noi, P.T.[Phan Thanh], Kappas, M.[Martin], Degener, J.[Jan],
Estimating Daily Maximum and Minimum Land Air Surface Temperature Using MODIS Land Surface Temperature Data and Ground Truth Data in Northern Vietnam,
RS(8), No. 12, 2016, pp. 1002.
DOI Link 1612
BibRef

Islam, T., Hulley, G.C., Malakar, N.K., Radocinski, R.G., Guillevic, P.C., Hook, S.J.,
A Physics-Based Algorithm for the Simultaneous Retrieval of Land Surface Temperature and Emissivity From VIIRS Thermal Infrared Data,
GeoRS(55), No. 1, January 2017, pp. 563-576.
IEEE DOI 1701
atmospheric humidity BibRef

Borbas, E.E.[E. Eva], Hulley, G.[Glynn], Feltz, M.[Michelle], Knuteson, R.[Robert], Hook, S.[Simon],
The Combined ASTER MODIS Emissivity over Land (CAMEL) Part 1: Methodology and High Spectral Resolution Application,
RS(10), No. 4, 2018, pp. xx-yy.
DOI Link 1805
BibRef

Feltz, M.[Michelle], Borbas, E.E.[E. Eva], Knuteson, R.[Robert], Hulley, G.[Glynn], Hook, S.[Simon],
The Combined ASTER and MODIS Emissivity over Land (CAMEL) Global Broadband Infrared Emissivity Product,
RS(10), No. 7, 2018, pp. xx-yy.
DOI Link 1808
BibRef

Feltz, M.[Michelle], Borbas, E.E.[E. Eva], Knuteson, R.[Robert], Hulley, G.[Glynn], Hook, S.[Simon],
The Combined ASTER MODIS Emissivity over Land (CAMEL) Part 2: Uncertainty and Validation,
RS(10), No. 5, 2018, pp. xx-yy.
DOI Link 1806
BibRef

Gao, L., Zhan, W., Huang, F., Quan, J., Lu, X., Wang, F., Ju, W., Zhou, J.,
Localization or Globalization? Determination of the Optimal Regression Window for Disaggregation of Land Surface Temperature,
GeoRS(55), No. 1, January 2017, pp. 477-490.
IEEE DOI 1701
climatology BibRef

Yang, Y.M.[Yong-Min], Qiu, J.X.[Jian-Xiu], Su, H.B.[Hong-Bo], Bai, Q.M.[Qing-Mei], Liu, S.[Suhua], Li, L.[Lu], Yu, Y.L.[Yi-Lei], Huang, Y.[Yaoxian],
A One-Source Approach for Estimating Land Surface Heat Fluxes Using Remotely Sensed Land Surface Temperature,
RS(9), No. 1, 2017, pp. xx-yy.
DOI Link 1702
BibRef

Bento, V.A.[Virgílio A.], DaCamara, C.C.[Carlos C.], Trigo, I.F.[Isabel F.], Martins, J.P.A.[João P. A.], Duguay-Tetzlaff, A.[Anke],
Improving Land Surface Temperature Retrievals over Mountainous Regions,
RS(9), No. 1, 2017, pp. xx-yy.
DOI Link 1702
BibRef

Frey, C.M.[Corinne Myrtha], Kuenzer, C.[Claudia], Dech, S.[Stefan],
Assessment of Mono- and Split-Window Approaches for Time Series Processing of LST from AVHRR: A TIMELINE Round Robin,
RS(9), No. 1, 2017, pp. xx-yy.
DOI Link 1702
BibRef

Ouyang, X.Y.[Xiao-Ying], Chen, D.M.[Dong-Mei], Duan, S.B.[Si-Bo], Lei, Y.H.[Yong-Hui], Dou, Y.[Youjun], Hu, G.[Guangcheng],
Validation and Analysis of Long-Term AATSR Land Surface Temperature Product in the Heihe River Basin, China,
RS(9), No. 2, 2017, pp. xx-yy.
DOI Link 1703
BibRef

Chen, Y.Y.[Yuan-Yuan], Duan, S.B.[Si-Bo], Ren, H.Z.[Hua-Zhong], Labed, J.[Jelila], Li, Z.L.[Zhao-Liang],
Algorithm Development for Land Surface Temperature Retrieval: Application to Chinese Gaofen-5 Data,
RS(9), No. 2, 2017, pp. xx-yy.
DOI Link 1703
BibRef

Chang, L., Song, S., Feng, G., Zhang, Y., Gao, G.,
Assessment of the Uncertainties in Arctic Low-Level Temperature Inversion Characteristics in Radio Occultation Observations,
GeoRS(55), No. 3, March 2017, pp. 1793-1803.
IEEE DOI 1703
Arctic BibRef

Chang, L., Feng, G., Zhang, Y., He, X.,
Effect of Cloud Fraction on Arctic Low-Level Temperature Inversions in AIRS Observations Over Both Land and Ocean,
GeoRS(56), No. 4, April 2018, pp. 2025-2032.
IEEE DOI 1804
Arctic, Clouds, Land surface temperature, Meteorology, Ocean temperature, Temperature measurement, cloud fraction (CF) BibRef

Hally, B.[Bryan], Wallace, L.[Luke], Reinke, K.[Karin], Jones, S.[Simon],
A Broad-Area Method for the Diurnal Characterisation of Upwelling Medium Wave Infrared Radiation,
RS(9), No. 2, 2017, pp. xx-yy.
DOI Link 1703
BibRef

Duan, S.B.[Si-Bo], Li, Z.L.[Zhao-Liang], Cheng, J.[Jie], Leng, P.[Pei],
Cross-satellite comparison of operational land surface temperature products derived from MODIS and ASTER data over bare soil surfaces,
PandRS(126), No. 1, 2017, pp. 1-10.
Elsevier DOI 1704
Land surface temperature (LST) BibRef

Duarte, L.[Lia], Teodoro, A.C.[Ana Cláudia], Gonçalves, J.A.[José Alberto], Ribeiro, J.[Joana], Flores, D.[Deolinda], Lopez-Gil, A.[Alexia], Dominguez-Lopez, A.[Alejandro], Angulo-Vinuesa, X.[Xabier], Martin-Lopez, S.[Sonia], Gonzalez-Herraez, M.[Miguel],
Distributed Temperature Measurement in a Self-Burning Coal Waste Pile through a GIS Open Source Desktop Application,
IJGI(6), No. 3, 2017, pp. xx-yy.
DOI Link 1704
BibRef

Cai, Y.[Yulin], Chen, G.[Gang], Wang, Y.[Yali], Yang, L.[Li],
Impacts of Land Cover and Seasonal Variation on Maximum Air Temperature Estimation Using MODIS Imagery,
RS(9), No. 3, 2017, pp. xx-yy.
DOI Link 1704
BibRef

Pivovarník, M., Khalsa, S.J.S., Jiménez-Muñoz, J.C., Zemek, F.,
Improved Temperature and Emissivity Separation Algorithm for Multispectral and Hyperspectral Sensors,
GeoRS(55), No. 4, April 2017, pp. 1944-1953.
IEEE DOI 1704
atmospheric radiation BibRef

Harris, L., Warren, M., Grant, M., Llewellyn, G.M.,
Spectral Characterization of the AisaOWL,
GeoRS(55), No. 5, May 2017, pp. 2751-2756.
IEEE DOI 1705
geophysical techniques, hyperspectral imaging, infrared detectors, remote sensing, temperature sensors, absolute temperature measurement, long-wave infrared region, sensor performance, thermal hyperspectral instrument, Hyperspectral imaging, Temperature measurement, Wavelength measurement. BibRef

Noi, P.T.[Phan Thanh], Degener, J.[Jan], Kappas, M.[Martin],
Comparison of Multiple Linear Regression, Cubist Regression, and Random Forest Algorithms to Estimate Daily Air Surface Temperature from Dynamic Combinations of MODIS LST Data,
RS(9), No. 5, 2017, pp. xx-yy.
DOI Link 1706
BibRef

Yang, Y.Z.[Yuan Z.], Cai, W.H.[Wen H.], Yang, J.[Jian],
Evaluation of MODIS Land Surface Temperature Data to Estimate Near-Surface Air Temperature in Northeast China,
RS(9), No. 5, 2017, pp. xx-yy.
DOI Link 1706
BibRef

Urbain, M.[Manon], Clerbaux, N.[Nicolas], Ipe, A.[Alessandro], Tornow, F.[Florian], Hollmann, R.[Rainer], Baudrez, E.[Edward], Blazquez, A.V.[Almudena Velazquez], Moreels, J.[Johan],
The CM SAF TOA Radiation Data Record Using MVIRI and SEVIRI,
RS(9), No. 5, 2017, pp. xx-yy.
DOI Link 1706
BibRef

Sun, H.[Hao], Wang, Y.M.[Yan-Mei], Liu, W.[Weihan], Yuan, S.Y.[Shu-Yun], Nie, R.W.[Ru-Wei],
Comparison of Three Theoretical Methods for Determining Dry and Wet Edges of the LST/FVC Space: Revisit of Method Physics,
RS(9), No. 6, 2017, pp. xx-yy.
DOI Link 1706
Land surface temperature and fractional vegetation coverage. BibRef

Zhou, J., Zhang, X., Zhan, W., Göttsche, F.M., Liu, S., Olesen, F.S., Hu, W., Dai, F.,
A Thermal Sampling Depth Correction Method for Land Surface Temperature Estimation From Satellite Passive Microwave Observation Over Barren Land,
GeoRS(55), No. 8, August 2017, pp. 4743-4756.
IEEE DOI 1708
Land surface, Land surface temperature, Microwave radiometry, Remote sensing, Satellites, Temperature measurement, Temperature sensors, Advanced Microwave Scanning Radiometer-Earth Observing System (AMSR-E), MODIS, land surface temperature, passive microwave (MW) remote sensing, soil heat conductionequation (SHCE), thermal, sampling, depth, (TSD) BibRef

Crosman, E.[Erik], Vazquez-Cuervo, J.[Jorge], Chin, T.M.[Toshio Michael],
Evaluation of the Multi-Scale Ultra-High Resolution (MUR) Analysis of Lake Surface Temperature,
RS(9), No. 7, 2017, pp. xx-yy.
DOI Link 1708
BibRef

Bian, Z.J.[Zun-Jian], Cao, B.[Biao], Li, H.[Hua], Du, Y.M.[Yong-Ming], Song, L.S.[Li-Sheng], Fan, W.J.[Wen-Jie], Xiao, Q.[Qing], Liu, Q.H.[Qin-Huo],
A Robust Inversion Algorithm for Surface Leaf and Soil Temperatures Using the Vegetation Clumping Index,
RS(9), No. 8, 2017, pp. xx-yy.
DOI Link 1708
BibRef
And: Addendum: RS(9), No. 10, 2017, pp. xx-yy.
DOI Link 1711
BibRef

Yang, Y.B.[Ying-Bao], Cao, C.[Chen], Pan, X.[Xin], Li, X.L.[Xiao-Long], Zhu, X.[Xi],
Downscaling Land Surface Temperature in an Arid Area by Using Multiple Remote Sensing Indices with Random Forest Regression,
RS(9), No. 8, 2017, pp. xx-yy.
DOI Link 1708
BibRef

Li, X.J.[Xiao-Jun], Xin, X.Z.[Xiao-Zhou], Jiao, J.J.[Jing-Jun], Peng, Z.Q.[Zhi-Qing], Zhang, H.L.[Hai-Long], Shao, S.S.[Shan-Shan], Liu, Q.H.[Qin-Huo],
Estimating Subpixel Surface Heat Fluxes through Applying Temperature-Sharpening Methods to MODIS Data,
RS(9), No. 8, 2017, pp. xx-yy.
DOI Link 1708
BibRef

Bian, Z.J.[Zun-Jian], Du, Y., Li, H.[Hua], Cao, B.[Biao], Huang, H.G.[Hua-Guo], Xiao, Q.[Qing], Liu, Q.H.[Qin-Huo],
Modeling the Temporal Variability of Thermal Emissions From Row-Planted Scenes Using a Radiosity and Energy Budget Method,
GeoRS(55), No. 10, October 2017, pp. 6010-6026.
IEEE DOI 1710
land surface temperature, energy balance model. BibRef

Bian, Z.J.[Zun-Jian], Cao, B.[Biao], Li, H.[Hua], Du, Y.M.[Yong-Ming], Huang, H.G.[Hua-Guo], Xiao, Q.[Qing], Liu, Q.H.[Qin-Huo],
Modeling the Distributions of Brightness Temperatures of a Cropland Study Area Using a Model that Combines Fast Radiosity and Energy Budget Methods,
RS(10), No. 5, 2018, pp. xx-yy.
DOI Link 1806
BibRef

Ye, X., Ren, H., Liu, R., Qin, Q., Liu, Y., Dong, J.,
Land Surface Temperature Estimate From Chinese Gaofen-5 Satellite Data Using Split-Window Algorithm,
GeoRS(55), No. 10, October 2017, pp. 5877-5888.
IEEE DOI 1710
land surface temperature, atmospheric column water vapors. BibRef

Ren, H., Ye, X., Liu, R., Dong, J., Qin, Q.,
Improving Land Surface Temperature and Emissivity Retrieval From the Chinese Gaofen-5 Satellite Using a Hybrid Algorithm,
GeoRS(56), No. 2, February 2018, pp. 1080-1090.
IEEE DOI 1802
emissivity, geophysical image processing, land surface temperature, remote sensing, temperature and emissivity separation (TES) algorithm BibRef

Gholamnia, M.[Mehdi], Alavipanah, S.K.[Seyed Kazem], Boloorani, A.D.[Ali Darvishi], Hamzeh, S.[Saeid], Kiavarz, M.[Majid],
Diurnal Air Temperature Modeling Based on the Land Surface Temperature,
RS(9), No. 9, 2017, pp. xx-yy.
DOI Link 1711
BibRef

Zhou, W.[Wang], Peng, B.[Bin], Shi, J.C.[Jian-Cheng], Wang, T.X.[Tian-Xing], Dhital, Y.P.[Yam Prasad], Yao, R.[Ruzhen], Yu, Y.[Yuechi], Lei, Z.T.[Zhong-Teng], Zhao, R.[Rui],
Estimating High Resolution Daily Air Temperature Based on Remote Sensing Products and Climate Reanalysis Datasets over Glacierized Basins: A Case Study in the Langtang Valley, Nepal,
RS(9), No. 9, 2017, pp. xx-yy.
DOI Link 1711
BibRef

Rosas, J.[Jorge], Houborg, R.[Rasmus], McCabe, M.F.[Matthew F.],
Sensitivity of Landsat 8 Surface Temperature Estimates to Atmospheric Profile Data: A Study Using MODTRAN in Dryland Irrigated Systems,
RS(9), No. 10, 2017, pp. xx-yy.
DOI Link 1711
BibRef

Roy, A.[Alexandre], Toose, P.[Peter], Derksen, C.[Chris], Rowlandson, T.[Tracy], Berg, A.[Aaron], Lemmetyinen, J.[Juha], Royer, A.[Alain], Tetlock, E.[Erica], Helgason, W.[Warren], Sonnentag, O.[Oliver],
Spatial Variability of L-Band Brightness Temperature during Freeze/Thaw Events over a Prairie Environment,
RS(9), No. 9, 2017, pp. xx-yy.
DOI Link 1711
BibRef

Eswar, R.[Rajasekaran], Sekhar, M.[Muddu], Bhattacharya, B.K.[Bimal K.], Bandyopadhyay, S.[Soumya],
Spatial Disaggregation of Latent Heat Flux Using Contextual Models over India,
RS(9), No. 9, 2017, pp. xx-yy.
DOI Link 1711
BibRef

Wang, W.H.[Wen-Hui], Cao, C.Y.[Chang-Yong], Bai, Y.[Yan], Blonski, S.[Slawomir], Schull, M.A.[Mitchell A.],
Assessment of the NOAA S-NPP VIIRS Geolocation Reprocessing Improvements,
RS(9), No. 10, 2017, pp. xx-yy.
DOI Link 1711
BibRef

Ling, F.[Feng], Foody, G.M.[Giles M.], Du, H.[Hao], Ban, X.[Xuan], Li, X.D.[Xiao-Dong], Zhang, Y.H.[Yi-Hang], Du, Y.[Yun],
Monitoring Thermal Pollution in Rivers Downstream of Dams with Landsat ETM+ Thermal Infrared Images,
RS(9), No. 11, 2017, pp. xx-yy.
DOI Link 1712
BibRef

Allen, M.A.[Michael A.], Voogt, J.A.[James A.], Christen, A.[Andreas],
Time-Continuous Hemispherical Urban Surface Temperatures,
RS(10), No. 1, 2018, pp. xx-yy.
DOI Link 1802
BibRef

Tarawally, M.[Musa], Xu, W.[Wenbo], Hou, W.M.[Wei-Ming], Mushore, T.D.[Terence Darlington],
Comparative Analysis of Responses of Land Surface Temperature to Long-Term Land Use/Cover Changes between a Coastal and Inland City: A Case of Freetown and Bo Town in Sierra Leone,
RS(10), No. 1, 2018, pp. xx-yy.
DOI Link 1802
BibRef

Parastatidis, D.[David], Mitraka, Z.[Zina], Chrysoulakis, N.[Nektrarios], Abrams, M.[Michael],
Online Global Land Surface Temperature Estimation from Landsat,
RS(9), No. 12, 2017, pp. xx-yy.
DOI Link 1802
BibRef

Yu, W.P.[Wen-Ping], Ma, M.[Mingguo], Li, Z.[Zhaoliang], Tan, J.[Junlei], Wu, A.[Adan],
New Scheme for Validating Remote-Sensing Land Surface Temperature Products with Station Observations,
RS(9), No. 12, 2017, pp. xx-yy.
DOI Link 1802
BibRef

Meng, X.[Xiangchen], Cheng, J.[Jie], Liang, S.L.[Shun-Lin],
Estimating Land Surface Temperature from Feng Yun-3C/MERSI Data Using a New Land Surface Emissivity Scheme,
RS(9), No. 12, 2017, pp. xx-yy.
DOI Link 1802
BibRef

Pérez-Planells, L.[Lluís], Valor, E.[Enric], Coll, C.[César], Niclòs, R.[Raquel],
Comparison and Evaluation of the TES and ANEM Algorithms for Land Surface Temperature and Emissivity Separation over the Area of Valencia, Spain,
RS(9), No. 12, 2017, pp. xx-yy.
DOI Link 1802
BibRef

Niclòs, R.[Raquel], Pérez-Planells, L.[Lluís], Coll, C.[César], Valiente, J.A.[José A.], Valor, E.[Enric],
Evaluation of the S-NPP VIIRS land surface temperature product using ground data acquired by an autonomous system at a rice paddy,
PandRS(135), No. Supplement C, 2018, pp. 1-12.
Elsevier DOI 1712
Land surface temperature, Emissivity, S-NPP VIIRS, Validation, Accuracy, Multiangular ground measurements BibRef

Wang, M.[Mengmeng], He, G.[Guojin], Zhang, Z.[Zhaoming], Wang, G.[Guizhou], Zhang, Z.[Zhengjia], Cao, X.[Xiaojie], Wu, Z.J.[Zhi-Jie], Liu, X.[Xiuguo],
Comparison of Spatial Interpolation and Regression Analysis Models for an Estimation of Monthly Near Surface Air Temperature in China,
RS(9), No. 12, 2017, pp. xx-yy.
DOI Link 1802
BibRef

Mira, M.[Maria], Ninyerola, M.[Miquel], Batalla, M.[Meritxell], Pesquer, L.[Lluís], Pons, X.[Xavier],
Improving Mean Minimum and Maximum Month-to-Month Air Temperature Surfaces Using Satellite-Derived Land Surface Temperature,
RS(9), No. 12, 2017, pp. xx-yy.
DOI Link 1802
BibRef

Lieberherr, G.[Gian], Riffler, M.[Michael], Wunderle, S.[Stefan],
Performance Assessment of Tailored Split-Window Coefficients for the Retrieval of Lake Surface Water Temperature from AVHRR Satellite Data,
RS(9), No. 12, 2017, pp. xx-yy.
DOI Link 1802
BibRef

Lieberherr, G.[Gian], Wunderle, S.[Stefan],
Lake Surface Water Temperature Derived from 35 Years of AVHRR Sensor Data for European Lakes,
RS(10), No. 7, 2018, pp. xx-yy.
DOI Link 1808
BibRef

Metz, M.[Markus], Andreo, V.[Verónica], Neteler, M.[Markus],
A New Fully Gap-Free Time Series of Land Surface Temperature from MODIS LST Data,
RS(9), No. 12, 2017, pp. xx-yy.
DOI Link 1802
BibRef

Wang, X.Y.[Xuan-Yu], Yao, Y.J.[Yun-Jun], Zhao, S.H.[Shao-Hua], Jia, K.[Kun], Zhang, X.T.[Xiao-Tong], Zhang, Y.[Yuhu], Zhang, L.[Lilin], Xu, J.[Jia], Chen, X.W.[Xiao-Wei],
MODIS-Based Estimation of Terrestrial Latent Heat Flux over North America Using Three Machine Learning Algorithms,
RS(9), No. 12, 2017, pp. xx-yy.
DOI Link 1802
BibRef

Tenjo, C., Rivera-Caicedo, J.P., Sabater, N., Servera, J.V.[J. Vicent], Alonso, L., Verrelst, J., Moreno, J.,
Design of a Generic 3-D Scene Generator for Passive Optical Missions and Its Implementation for the ESA's FLEX/Sentinel-3 Tandem Mission,
GeoRS(56), No. 3, March 2018, pp. 1290-1307.
IEEE DOI 1804
atmospheric techniques, geophysical techniques, land surface temperature, radiative transfer, radiometers, surface-atmosphere coupling BibRef

Ditri, A.L.[Angela L.], Minnett, P.J.[Peter J.], Liu, Y.[Yang], Kilpatrick, K.[Katherine], Kumar, A.[Ajoy],
The Accuracies of Himawari-8 and MTSAT-2 Sea-Surface Temperatures in the Tropical Western Pacific Ocean,
RS(10), No. 2, 2018, pp. xx-yy.
DOI Link 1804
BibRef

Policelli, F.[Frederick], Hubbard, A.[Alfred], Jung, H.C.[Hahn Chul], Zaitchik, B.[Ben], Ichoku, C.[Charles],
Lake Chad Total Surface Water Area as Derived from Land Surface Temperature and Radar Remote Sensing Data,
RS(10), No. 2, 2018, pp. xx-yy.
DOI Link 1804
BibRef

Cristóbal, J.[Jordi], Jiménez-Muñoz, J.C.[Juan C.], Prakash, A.[Anupma], Mattar, C.[Cristian], Skokovic, D.[Dražen], Sobrino, J.A.[José A.],
An Improved Single-Channel Method to Retrieve Land Surface Temperature from the Landsat-8 Thermal Band,
RS(10), No. 3, 2018, pp. xx-yy.
DOI Link 1804
BibRef

Wilkes, T.C.[Thomas Charles], Stanger, L.R.[Leigh Russell], Willmott, J.R.[Jon Raffe], Pering, T.D.[Tom David], McGonigle, A.J.S.[Andrew John Samuel], England, R.A.[Rebecca Anne],
The Development of a Low-Cost, Near Infrared, High-Temperature Thermal Imaging System and Its Application to the Retrieval of Accurate Lava Lake Temperatures at Masaya Volcano, Nicaragua,
RS(10), No. 3, 2018, pp. xx-yy.
DOI Link 1804
BibRef

Zou, Z.[Zhaoxu], Zhan, W.F.[Wen-Feng], Liu, Z.[Zihan], Bechtel, B.[Benjamin], Gao, L.[Lun], Hong, F.[Falu], Huang, F.[Fan], Lai, J.[Jiameng],
Enhanced Modeling of Annual Temperature Cycles with Temporally Discrete Remotely Sensed Thermal Observations,
RS(10), No. 4, 2018, pp. xx-yy.
DOI Link 1805
BibRef

Liu, H.M.[Hui-Min], Zhan, Q.M.[Qing-Ming], Yang, C.[Chen], Wang, J.[Jiong],
Characterizing the Spatio-Temporal Pattern of Land Surface Temperature through Time Series Clustering: Based on the Latent Pattern and Morphology,
RS(10), No. 4, 2018, pp. xx-yy.
DOI Link 1805
BibRef

Bulgin, C.E.[Claire E.], Merchant, C.J.[Christopher J.], Ghent, D.[Darren], Klüser, L.[Lars], Popp, T.[Thomas], Poulsen, C.[Caroline], Sogacheva, L.[Larisa],
Quantifying Uncertainty in Satellite-Retrieved Land Surface Temperature from Cloud Detection Errors,
RS(10), No. 4, 2018, pp. xx-yy.
DOI Link 1805
BibRef

Wang, D.C.[Dong-Chuan], Wang, F.C.[Fei-Cui], Huang, Y.[Yong], Duan, X.[Xingwu], Liu, J.[Jinya], Hu, B.X.[Bing-Xu], Sun, Z.[Zhichao], Chen, J.[Junhe],
Examining the Effects of Hydropower Station Construction on the Surface Temperature of the Jinsha River Dry-Hot Valley at Different Seasons,
RS(10), No. 4, 2018, pp. xx-yy.
DOI Link 1805
BibRef

Tang, B.[Bijian], Zhao, X.[Xiang], Zhao, W.[Wenqian],
Local Effects of Forests on Temperatures across Europe,
RS(10), No. 4, 2018, pp. xx-yy.
DOI Link 1805
BibRef

Hall, D.K.[Dorothy K.], Cullather, R.I.[Richard I.], Di Girolamo, N.E.[Nicolo E.], Comiso, J.C.[Josefino C.], Medley, B.C.[Brooke C.], Nowicki, S.M.[Sophie M.],
A Multilayer Surface Temperature, Surface Albedo, and Water Vapor Product of Greenland from MODIS,
RS(10), No. 4, 2018, pp. xx-yy.
DOI Link 1805
BibRef

Fang, L.[Li], Zhan, X.[Xiwu], Hain, C.R.[Christopher R.], Yin, J.[Jifu], Liu, J.C.[Ji-Cheng], Schull, M.A.[Mitchell A.],
An Assessment of the Impact of Land Thermal Infrared Observation on Regional Weather Forecasts Using Two Different Data Assimilation Approaches,
RS(10), No. 4, 2018, pp. xx-yy.
DOI Link 1805
BibRef

Zeng, C.[Chao], Long, D.[Di], Shen, H.[Huanfeng], Wu, P.[Penghai], Cui, Y.[Yaokui], Hong, Y.[Yang],
A two-step framework for reconstructing remotely sensed land surface temperatures contaminated by cloud,
PandRS(141), 2018, pp. 30-45.
Elsevier DOI 1806
Land surface temperature, Reconstruction, Multi-temporal information, Surface energy balance, MODIS BibRef

Wang, C.Y.[Chu-Yuan], Middel, A.[Ariane], Myint, S.W.[Soe W.], Kaplan, S.[Shai], Brazel, A.J.[Anthony J.], Lukasczyk, J.[Jonas],
Assessing local climate zones in arid cities: The case of Phoenix, Arizona and Las Vegas, Nevada,
PandRS(141), 2018, pp. 59-71.
Elsevier DOI 1806
Local climate zone, Land use land cover, Sky view factor, Land surface temperature, Phoenix, Las Vegas BibRef

Chen, T.Y.[Tian-Yang], Xie, Y.C.[Yi-Chun], Liu, C.[Chao], Bai, Y.F.[Yong-Fei], Zhang, A.B.[An-Bing], Mao, L.S.[Li-Shen], Fan, S.[Siyu],
Trend Analysis of Relationship between Primary Productivity, Precipitation and Temperature in Inner Mongolia,
IJGI(7), No. 6, 2018, pp. xx-yy.
DOI Link 1806
BibRef

Hssaine, B.A.[Bouchra Ait], Ezzahar, J.[Jamal], Jarlan, L.[Lionel], Merlin, O.[Olivier], Khabba, S.[Said], Brut, A.[Aurore], Er-Raki, S.[Salah], Elfarkh, J.[Jamal], Cappelaere, B.[Bernard], Chehbouni, G.[Ghani],
Combining a Two Source Energy Balance Model Driven by MODIS and MSG-SEVIRI Products with an Aggregation Approach to Estimate Turbulent Fluxes over Sparse and Heterogeneous Vegetation in Sahel Region (Niger),
RS(10), No. 6, 2018, pp. xx-yy.
DOI Link 1806
BibRef

Ouyang, X.Y.[Xiao-Ying], Chen, D.M.[Dong-Mei], Lei, Y.H.[Yong-Hui],
A Generalized Evaluation Scheme for Comparing Temperature Products from Satellite Observations, Numerical Weather Model, and Ground Measurements Over the Tibetan Plateau,
GeoRS(56), No. 7, July 2018, pp. 3876-3894.
IEEE DOI 1807
atmospheric techniques, land surface temperature, numerical analysis, remote sensing, weather forecasting, surface temperature BibRef

Pede, T.[Timothy], Mountrakis, G.[Giorgos],
An empirical comparison of interpolation methods for MODIS 8-day land surface temperature composites across the conterminous Unites States,
PandRS(142), 2018, pp. 137-150.
Elsevier DOI 1807
Land surface temperature, MODIS, 8-day, Interpolation, Method assessment, Cloud BibRef

Hong, F.[Falu], Zhan, W.F.[Wen-Feng], Göttsche, F.M.[Frank-M.], Liu, Z.[Zihan], Zhou, J.[Ji], Huang, F.[Fan], Lai, J.[Jiameng], Li, M.[Manchun],
Comprehensive assessment of four-parameter diurnal land surface temperature cycle models under clear-sky,
PandRS(142), 2018, pp. 190-204.
Elsevier DOI 1807
Land surface temperature, Diurnal temperature cycle, Polar-orbiting satellite, Thermal remote sensing, Model comparison BibRef

Kang, J.[Jian], Tan, J.[Junlei], Jin, R.[Rui], Li, X.[Xin], Zhang, Y.[Yang],
Reconstruction of MODIS Land Surface Temperature Products Based on Multi-Temporal Information,
RS(10), No. 7, 2018, pp. xx-yy.
DOI Link 1808
BibRef

Ermida, S.L.[Sofia L.], Trigo, I.F.[Isabel F.], Da Camara, C.C.[Carlos C.], Pires, A.C.[Ana C.],
A Methodology to Simulate LST Directional Effects Based on Parametric Models and Landscape Properties,
RS(10), No. 7, 2018, pp. xx-yy.
DOI Link 1808
BibRef

White, C.H.[Charles H.], Heidinger, A.K.[Andrew K.], Ackerman, S.A.[Steven A.], McIntyre, P.B.[Peter B.],
A Long-Term Fine-Resolution Record of AVHRR Surface Temperatures for the Laurentian Great Lakes,
RS(10), No. 8, 2018, pp. xx-yy.
DOI Link 1809
BibRef

Bento, V.A.[Virgílio A.], Trigo, I.F.[Isabel F.], Gouveia, C.M.[Célia M.], Da Camara, C.C.[Carlos C.],
Contribution of Land Surface Temperature (TCI) to Vegetation Health Index: A Comparative Study Using Clear Sky and All-Weather Climate Data Records,
RS(10), No. 9, 2018, pp. xx-yy.
DOI Link 1810
BibRef

Xia, H.P.[Hai-Ping], Chen, Y.H.[Yun-Hao], Zhao, Y.T.[Yu-Tong], Chen, Z.X.[Zi-Xuan],
'Regression-then-Fusion' or 'Fusion-then-Regression'? A Theoretical Analysis for Generating High Spatiotemporal Resolution Land Surface Temperatures,
RS(10), No. 9, 2018, pp. xx-yy.
DOI Link 1810
BibRef

Malbéteau, Y.[Yoann], Parkes, S.[Stephen], Aragon, B.[Bruno], Rosas, J.[Jorge], McCabe, M.F.[Matthew F.],
Capturing the Diurnal Cycle of Land Surface Temperature Using an Unmanned Aerial Vehicle,
RS(10), No. 9, 2018, pp. xx-yy.
DOI Link 1810
BibRef

García-Santos, V.[Vicente], Cuxart, J.[Joan], Martínez-Villagrasa, D.[Daniel], Jiménez, M.A.[Maria Antònia], Simó, G.[Gemma],
Comparison of Three Methods for Estimating Land Surface Temperature from Landsat 8-TIRS Sensor Data,
RS(10), No. 9, 2018, pp. xx-yy.
DOI Link 1810
BibRef

Schreck, C.J.[Carl J.], Lee, H.T.[Hai-Tien], Knapp, K.R.[Kenneth R.],
HIRS Outgoing Longwave Radiation: Daily Climate Data Record: Application toward Identifying Tropical Subseasonal Variability,
RS(10), No. 9, 2018, pp. xx-yy.
DOI Link 1810
BibRef

Andrews, M.J., Johnson, J.T., Jezek, K.C., Li, H., Bringer, A., Chen, C., Belgiovane, D.J., Leuski, V., Macelloni, G., Brogioni, M.,
The Ultrawideband Software-Defined Microwave Radiometer: Instrument Description and Initial Campaign Results,
GeoRS(56), No. 10, October 2018, pp. 5923-5935.
IEEE DOI 1810
Antennas, Temperature measurement, Antenna measurements, Switches, Microwave radiometry, Ice, Calibration, Calibration, ultrawideband radiation BibRef

Tang, B.,
Nonlinear Split-Window Algorithms for Estimating Land and Sea Surface Temperatures From Simulated Chinese Gaofen-5 Satellite Data,
GeoRS(56), No. 11, November 2018, pp. 6280-6289.
IEEE DOI 1811
Atmospheric modeling, Ocean temperature, Land surface temperature, Sea surface, Land surface, Satellites, thermal infrared (TIR) BibRef

Qin, Y.[Yun], Ren, G.[Guoyu], Zhai, T.L.[Tian-Lin], Zhang, P.F.[Pan-Feng], Wen, K.M.[Kang-Min],
A New Methodology for Estimating the Surface Temperature Lapse Rate Based on Grid Data and Its Application in China,
RS(10), No. 10, 2018, pp. xx-yy.
DOI Link 1811
BibRef

Rahaman, K.R.[Khan Rubayet], Ahmed, M.R.[M. Razu], Hassan, Q.K.[Quazi K.],
Using Satellite-Borne Remote Sensing Data in Generating Local Warming Maps with Enhanced Resolution,
IJGI(7), No. 10, 2018, pp. xx-yy.
DOI Link 1811
BibRef

Marchand, N.[Nicolas], Royer, A.[Alain], Krinner, G.[Gerhard], Roy, A.[Alexandre], Langlois, A.[Alexandre], Vargel, C.[Céline],
Snow-Covered Soil Temperature Retrieval in Canadian Arctic Permafrost Areas, Using a Land Surface Scheme Informed with Satellite Remote Sensing Data,
RS(10), No. 11, 2018, pp. xx-yy.
DOI Link 1812
BibRef

Brodzik, M.J.[Mary J.], Long, D.G.[David G.], Hardman, M.A.[Molly A.],
Best Practices in Crafting the Calibrated, Enhanced-Resolution Passive-Microwave EASE-Grid 2.0 Brightness Temperature Earth System Data Record,
RS(10), No. 11, 2018, pp. xx-yy.
DOI Link 1812
BibRef

Zuo, S.[Shudi], Dai, S.Q.[Shao-Qing], Song, X.D.[Xiao-Dong], Xu, C.D.[Cheng-Dong], Liao, Y.[Yilan], Chang, W.Y.[Wei-Yin], Chen, Q.[Qi], Li, Y.[Yaying], Tang, J.F.[Jian-Feng], Man, W.[Wang], Ren, Y.[Yin],
Determining the Mechanisms that Influence the Surface Temperature of Urban Forest Canopies by Combining Remote Sensing Methods, Ground Observations, and Spatial Statistical Models,
RS(10), No. 11, 2018, pp. xx-yy.
DOI Link 1812
BibRef

Lorenz, C.[Christof], Montzka, C.[Carsten], Jagdhuber, T.[Thomas], Laux, P.[Patrick], Kunstmann, H.[Harald],
Long-Term and High-Resolution Global Time Series of Brightness Temperature from Copula-Based Fusion of SMAP Enhanced and SMOS Data,
RS(10), No. 11, 2018, pp. xx-yy.
DOI Link 1812
BibRef

Lu, L.[Lei], Zhang, T.[Tingjun], Wang, T.J.[Tie-Jun], Zhou, X.M.[Xiao-Ming],
Evaluation of Collection-6 MODIS Land Surface Temperature Product Using Multi-Year Ground Measurements in an Arid Area of Northwest China,
RS(10), No. 11, 2018, pp. xx-yy.
DOI Link 1812
BibRef

Liu, Y.H.[Ying-Hui], Dworak, R.[Richard], Key, J.[Jeffrey],
Ice Surface Temperature Retrieval from a Single Satellite Imager Band,
RS(10), No. 12, 2018, pp. xx-yy.
DOI Link 1901
BibRef

Choi, Y.Y.[Youn-Young], Suh, M.S.[Myoung-Seok],
Development of Himawari-8/Advanced Himawari Imager (AHI) Land Surface Temperature Retrieval Algorithm,
RS(10), No. 12, 2018, pp. xx-yy.
DOI Link 1901
BibRef

Liu, T.X.[Ting-Xiang], Yu, L.X.[Ling-Xue], Bu, K.[Kun], Yan, F.Q.[Feng-Qin], Zhang, S.[Shuwen],
Seasonal Local Temperature Responses to Paddy Field Expansion from Rain-Fed Farmland in the Cold and Humid Sanjiang Plain of China,
RS(10), No. 12, 2018, pp. xx-yy.
DOI Link 1901
BibRef

He, X.L.[Xin-Lei], Xu, T.R.[Tong-Ren], Bateni, S.M.[Sayed M.], Neale, C.M.U.[Christopher M. U.], Auligne, T.[Thomas], Liu, S.M.[Shao-Min], Wang, K.C.[Kai-Cun], Mao, K.B.[Ke-Biao], Yao, Y.J.[Yun-Jun],
Evaluation of the Weak Constraint Data Assimilation Approach for Estimating Turbulent Heat Fluxes at Six Sites,
RS(10), No. 12, 2018, pp. xx-yy.
DOI Link 1901
BibRef

Hakuba, M.Z., Stephens, G.L., Christophe, B., Nash, A.E., Foulon, B., Bettadpur, S.V., Tapley, B.D., Webb, F.H.,
Earth's Energy Imbalance Measured From Space,
GeoRS(57), No. 1, January 2019, pp. 32-45.
IEEE DOI 1901
Extraterrestrial measurements, Sea measurements, Oceans, Heating systems, Space vehicles, Earth, Pressure measurement, remote sensing BibRef

García-Santos, V., Cuxart, J., Jiménez, M.A., Martínez-Villagrasa, D., Simó, G., Picos, R., Caselles, V.,
Study of Temperature Heterogeneities at Sub-Kilometric Scales and Influence on Surface-Atmosphere Energy Interactions,
GeoRS(57), No. 2, February 2019, pp. 640-654.
IEEE DOI 1901
Land surface temperature, Sensors, Temperature measurement, Unmanned aerial vehicles, Land surface, Ocean temperature, unmanned aerial vehicle (UAV) BibRef

Pavlidou, E.[Efthymia], Van der Meijde, M.[Mark], Van der Werff, H.[Harald], Hecker, C.[Christoph],
Time Series Analysis of Land Surface Temperatures in 20 Earthquake Cases Worldwide,
RS(11), No. 1, 2018, pp. xx-yy.
DOI Link 1901
BibRef

Wang, Y.L.[You-Lin], Wu, C.R.[Chau-Ron],
Enhanced Warming and Intensification of the Kuroshio Extension, 1999-2013,
RS(11), No. 1, 2019, pp. xx-yy.
DOI Link 1901
BibRef

Wu, C.R.[Chau-Ron], Wang, Y.L.[You-Lin], Chao, S.Y.[Shenn-Yu],
Disassociation of the Kuroshio Current with the Pacific Decadal Oscillation Since 1999,
RS(11), No. 3, 2019, pp. xx-yy.
DOI Link 1902
BibRef

Cheng, J.[Jie], Liang, S.L.[Shun-Lin], Yao, Y.J.[Yun-Jun], Ren, B.Y.[Bai-Yang], Shi, L.P.[Lin-Peng], Liu, H.[Hao],
A Comparative Study of Three Land Surface Broadband Emissivity Datasets from Satellite Data,
RS(6), No. 1, 2013, pp. 111-134.
DOI Link 1402
BibRef

Feng, Y.J.[Yong-Jiu], Gao, C.[Chen], Tong, X.H.[Xiao-Hua], Chen, S.R.[Shu-Rui], Lei, Z.K.[Zhen-Kun], Wang, J.F.[Jia-Feng],
Spatial Patterns of Land Surface Temperature and Their Influencing Factors: A Case Study in Suzhou, China,
RS(11), No. 2, 2019, pp. xx-yy.
DOI Link 1902
BibRef

Liu, C.G.[Chun-Guang], Shi, J.C.[Jian-Cheng], Wang, T.X.[Tian-Xing], Ram, K.[Kirpa], Zhao, T.J.[Tian-Jie],
Mathematical Assessment of the Effects of Substituting the Band Radiative Transfer Equation (RTE) for the Spectral RTE in the Applications of Earth's Surface Temperature Retrievals from Spaceborne Infrared Imageries,
RS(11), No. 3, 2019, pp. xx-yy.
DOI Link 1902
BibRef

Wu, P.H.[Peng-Hai], Yin, Z.X.[Zhi-Xiang], Yang, H.[Hui], Wu, Y.L.[Yan-Lan], Ma, X.S.[Xiao-Shuang],
Reconstructing Geostationary Satellite Land Surface Temperature Imagery Based on a Multiscale Feature Connected Convolutional Neural Network,
RS(11), No. 3, 2019, pp. xx-yy.
DOI Link 1902
BibRef

Zheng, Y.[Yitong], Ren, H.Z.[Hua-Zhong], Guo, J.X.[Jin-Xin], Ghent, D.[Darren], Tansey, K.[Kevin], Hu, X.[Xingbang], Nie, J.[Jing], Chen, S.S.[Shan-Shan],
Land Surface Temperature Retrieval from Sentinel-3A Sea and Land Surface Temperature Radiometer, Using a Split-Window Algorithm,
RS(11), No. 6, 2019, pp. xx-yy.
DOI Link 1903
BibRef

Liou, Y., Le, M.S., Chien, H.,
Normalized Difference Latent Heat Index for Remote Sensing of Land Surface Energy Fluxes,
GeoRS(57), No. 3, March 2019, pp. 1423-1433.
IEEE DOI 1903
evaporation, geophysical image processing, hydrological techniques, land surface temperature, latent heat, water availability BibRef

Acito, N., Diani, M., Corsini, G.,
Subspace-Based Temperature and Emissivity Separation Algorithms in LWIR Hyperspectral Data,
GeoRS(57), No. 3, March 2019, pp. 1523-1537.
IEEE DOI 1903
emissivity, geophysical image processing, maximum likelihood estimation, remote sensing, temperature emissivity separation BibRef

Amazirh, A.[Abdelhakim], Merlin, O.[Olivier], Er-Raki, S.[Salah],
Including Sentinel-1 radar data to improve the disaggregation of MODIS land surface temperature data,
PandRS(150), 2019, pp. 11-26.
Elsevier DOI 1903
LST, Disaggregation, Soil moisture, Sentinel-1, MODIS/Terra, Landsat BibRef

Martin, M.A.[Maria Anna], Ghent, D.[Darren], Pires, A.C.[Ana Cordeiro], Göttsche, F.M.[Frank-Michael], Cermak, J.[Jan], Remedios, J.J.[John J.],
Comprehensive In Situ Validation of Five Satellite Land Surface Temperature Data Sets over Multiple Stations and Years,
RS(11), No. 5, 2019, pp. xx-yy.
DOI Link 1903
BibRef

Sansivero, F.[Fabio], Vilardo, G.[Giuseppe],
Processing Thermal Infrared Imagery Time-Series from Volcano Permanent Ground-Based Monitoring Network. Latest Methodological Improvements to Characterize Surface Temperatures Behavior of Thermal Anomaly Areas,
RS(11), No. 5, 2019, pp. xx-yy.
DOI Link 1903
BibRef

Kelly, J.[Julia], Kljun, N.[Natascha], Olsson, P.O.[Per-Ola], Mihai, L.[Laura], Liljeblad, B.[Bengt], Weslien, P.[Per], Klemedtsson, L.[Leif], Eklundh, L.[Lars],
Challenges and Best Practices for Deriving Temperature Data from an Uncalibrated UAV Thermal Infrared Camera,
RS(11), No. 5, 2019, pp. xx-yy.
DOI Link 1903
BibRef

Fan, L.[Lei], Al-Yaari, A., Frappart, F.[Frédéric], Swenson, J.J.[Jennifer J.], Xiao, Q.[Qing], Wen, J.[Jianguang], Jin, R.[Rui], Kang, J.[Jian], Li, X.J.[Xiao-Jun], Fernandez-Moran, R., Wigneron, J.P.,
Mapping Soil Moisture at a High Resolution over Mountainous Regions by Integrating In Situ Measurements, Topography Data, and MODIS Land Surface Temperatures,
RS(11), No. 6, 2019, pp. xx-yy.
DOI Link 1903
BibRef

Liu, Z.H.[Zi-Han], Zhan, W.F.[Wen-Feng], Lai, J.M.[Jia-Meng], Hong, F.[Falu], Quan, J.L.[Jin-Ling], Bechtel, B.[Benjamin], Huang, F.[Fan], Zou, Z.[Zhaoxu],
Balancing prediction accuracy and generalization ability: A hybrid framework for modelling the annual dynamics of satellite-derived land surface temperatures,
PandRS(151), 2019, pp. 189-206.
Elsevier DOI 1904
Land surface temperature, Annual temperature cycle, LST dynamics, Prediction accuracy, Generalization ability BibRef

Zhang, Z.W.[Zhen-Wei], Du, Q.[Qingyun],
A Bayesian Kriging Regression Method to Estimate Air Temperature Using Remote Sensing Data,
RS(11), No. 7, 2019, pp. xx-yy.
DOI Link 1904
BibRef

Zhao, W.[Wei], He, J.[Juelin], Wu, Y.H.[Yan-Hong], Xiong, D.H.[Dong-Hong], Wen, F.P.[Feng-Ping], Li, A.[Ainong],
An Analysis of Land Surface Temperature Trends in the Central Himalayan Region Based on MODIS Products,
RS(11), No. 8, 2019, pp. xx-yy.
DOI Link 1905
BibRef

Zhao, W.[Wei], Wu, H.[Hua], Yin, G.[Gaofei], Duan, S.B.[Si-Bo],
Normalization of the temporal effect on the MODIS land surface temperature product using random forest regression,
PandRS(152), 2019, pp. 109-118.
Elsevier DOI 1905
Land surface temperature, Temporal effect, MODIS, Random forest regression, Normalization BibRef

Xu, J.[Jia], Yao, Y.J.[Yun-Jun], Liang, S.L.[Shun-Lin], Liu, S.M.[Shao-Min], Fisher, J.B.[Joshua B.], Jia, K.[Kun], Zhang, X.T.[Xiao-Tong], Lin, Y.[Yi], Zhang, L.L.[Li-Lin], Chen, X.W.[Xiao-Wei],
Merging the MODIS and Landsat Terrestrial Latent Heat Flux Products Using the Multiresolution Tree Method,
GeoRS(57), No. 5, May 2019, pp. 2811-2823.
IEEE DOI 1905
atmospheric boundary layer, atmospheric techniques, atmospheric temperature, land cover, land surface temperature, terrestrial latent heat flux (LE) BibRef

Xu, J.[Jia], Yao, Y.J.[Yun-Jun], Tan, K.[Kanran], Li, Y.[Yufu], Liu, S.M.[Shao-Min], Shang, K.[Ke], Jia, K.[Kun], Zhang, X.T.[Xiao-Tong], Chen, X.W.[Xiao-Wei], Bei, X.Y.[Xiang-Yi],
Integrating Latent Heat Flux Products from MODIS and Landsat Data Using Multi-Resolution Kalman Filter Method in the Midstream of Heihe River Basin of Northwest China,
RS(11), No. 15, 2019, pp. xx-yy.
DOI Link 1908
BibRef

Wang, S.[Shasha], Hu, D.[Deyong], Chen, S.S.[Shan-Shan], Yu, C.[Chen],
A Partition Modeling for Anthropogenic Heat Flux Mapping in China,
RS(11), No. 9, 2019, pp. xx-yy.
DOI Link 1905
BibRef

Ghent, D.[Darren], Veal, K.[Karen], Trent, T.[Tim], Dodd, E.[Emma], Sembhi, H.[Harjinder], Remedios, J.[John],
A New Approach to Defining Uncertainties for MODIS Land Surface Temperature,
RS(11), No. 9, 2019, pp. xx-yy.
DOI Link 1905
BibRef

Caputo, T.[Teresa], Sessa, E.B.[Eliana Bellucci], Silvestri, M.[Malvina], Buongiorno, M.F.[Maria Fabrizia], Musacchio, M.[Massimo], Sansivero, F.[Fabio], Vilardo, G.[Giuseppe],
Surface Temperature Multiscale Monitoring by Thermal Infrared Satellite and Ground Images at Campi Flegrei Volcanic Area (Italy),
RS(11), No. 9, 2019, pp. xx-yy.
DOI Link 1905
BibRef

Liu, Z.Y.[Zi-Yan], Sun, Y.Q.[Yue-Qiang], Bai, W.H.[Wei-Hua], Xia, J.M.[Jun-Ming], Tan, G.Y.[Guang-Yuan], Cheng, C.[Cheng], Du, Q.[Qifei], Wang, X.Y.[Xian-Yi], Zhao, D.Y.[Dan-Yang], Tian, Y.[Yusen], Meng, X.G.[Xiang-Guang], Liu, C.L.[Cong-Liang], Cai, Y.[Yuerong], Wang, D.W.[Dong-Wei],
Validation of Preliminary Results of Thermal Tropopause Derived from FY-3C GNOS Data,
RS(11), No. 9, 2019, pp. xx-yy.
DOI Link 1905
BibRef

Bartkowiak, P.[Paulina], Castelli, M.[Mariapina], Notarnicola, C.[Claudia],
Downscaling Land Surface Temperature from MODIS Dataset with Random Forest Approach over Alpine Vegetated Areas,
RS(11), No. 11, 2019, pp. xx-yy.
DOI Link 1906
BibRef

Wang, Y.[Yipu], Li, R.[Rui], Min, Q.L.[Qi-Long], Zhang, L.[Leiming], Yu, G.R.[Gui-Rui], Bergeron, Y.[Yves],
Estimation of Vegetation Latent Heat Flux over Three Forest Sites in ChinaFLUX using Satellite Microwave Vegetation Water Content Index,
RS(11), No. 11, 2019, pp. xx-yy.
DOI Link 1906
BibRef

Lai, Z., Kiang, J.,
Brightness Temperatures From Very Lossy Medium With Near-Field Bistatic Transmission Coefficients,
GeoRS(57), No. 7, July 2019, pp. 4407-4416.
IEEE DOI 1907
Brightness temperature, Time-domain analysis, Propagation losses, Ocean temperature, Scattering, Finite difference methods, Planck's law BibRef

Zhang, X., Zhou, J., Göttsche, F., Zhan, W., Liu, S., Cao, R.,
A Method Based on Temporal Component Decomposition for Estimating 1-km All-Weather Land Surface Temperature by Merging Satellite Thermal Infrared and Passive Microwave Observations,
GeoRS(57), No. 7, July 2019, pp. 4670-4691.
IEEE DOI 1907
BibRef
And: Correction: GeoRS(57), No. 8, August 2019, pp. 6254-6254.
IEEE DOI 1908
Land surface temperature, Satellites, Remote sensing, Spatial resolution, MODIS, Temperature sensors, Clouds, All weather, thermal infrared (TIR) BibRef

Lv, S., Zeng, Y., Su, Z., Wen, J.,
A Closed-Form Expression of Soil Temperature Sensing Depth at L-Band,
GeoRS(57), No. 7, July 2019, pp. 4889-4897.
IEEE DOI 1907
Temperature sensors, Temperature measurement, Soil moisture, Moisture, Optical sensors, Microwave remote sensing, soil temperature sensing depth BibRef

Peng, Y., Li, W., Luo, X., Li, H.,
A Geographically and Temporally Weighted Regression Model for Spatial Downscaling of MODIS Land Surface Temperatures Over Urban Heterogeneous Regions,
GeoRS(57), No. 7, July 2019, pp. 5012-5027.
IEEE DOI 1907
Land surface temperature, Spatial resolution, Remote sensing, Earth, Artificial satellites, Thermal sensors, Land surface, time series BibRef

Pinker, R.T.[Rachel T.], Ma, Y.T.[Ying-Tao], Chen, W.[Wen], Hulley, G.[Glynn], Borbas, E.[Eva], Islam, T.[Tanvir], Hain, C.[Chris], Cawse-Nicholson, K.[Kerry], Hook, S.[Simon], Basara, J.[Jeff],
Towards a Unified and Coherent Land Surface Temperature Earth System Data Record from Geostationary Satellites,
RS(11), No. 12, 2019, pp. xx-yy.
DOI Link 1907
BibRef

Heinemann, G.[Günther], Glaw, L.[Lukas], Willmes, S.[Sascha],
A Satellite-Based Climatology of Wind-Induced Surface Temperature Anomalies for the Antarctic,
RS(11), No. 13, 2019, pp. xx-yy.
DOI Link 1907
BibRef

Cao, B., Gastellu-Etchegorry, J., Du, Y., Li, H., Bian, Z., Hu, T., Fan, W., Xiao, Q., Liu, Q.,
Evaluation of Four Kernel-Driven Models in the Thermal Infrared Band,
GeoRS(57), No. 8, August 2019, pp. 5456-5475.
IEEE DOI 1908
land surface temperature, vegetation, TIR region, physical models, directional anisotropy patterns, LSF-Li model, RL model, land surface temperature (LST) BibRef

AlJassar, H.K.[Hala K.], Temimi, M.[Marouane], Entekhabi, D.[Dara], Petrov, P.[Peter], AlSarraf, H.[Hussain], Kokkalis, P.[Panagiotis], Roshni, N.[Nair],
Forward Simulation of Multi-Frequency Microwave Brightness Temperature over Desert Soils in Kuwait and Comparison with Satellite Observations,
RS(11), No. 14, 2019, pp. xx-yy.
DOI Link 1908
BibRef

Sun, D.L.[Dong-Lian], Li, Y.[Yu], Zhan, X.[Xiwu], Houser, P.[Paul], Yang, C.[Chaowei], Chiu, L.[Long], Yang, R.X.[Rui-Xin],
Land Surface Temperature Derivation under All Sky Conditions through Integrating AMSR-E/AMSR-2 and MODIS/GOES Observations,
RS(11), No. 14, 2019, pp. xx-yy.
DOI Link 1908
BibRef

Ji, L.[Lei], Senay, G.B.[Gabriel B.], Velpuri, N.M.[Naga M.], Kagone, S.[Stefanie],
Evaluating the Temperature Difference Parameter in the SSEBop Model with Satellite-Observed Land Surface Temperature Data,
RS(11), No. 16, 2019, pp. xx-yy.
DOI Link 1909
BibRef

Sun, Z.Y.[Zhang-Yu], Zhang, B.[Bao], Yao, Y.[Yibin],
A Global Model for Estimating Tropospheric Delay and Weighted Mean Temperature Developed with Atmospheric Reanalysis Data from 1979 to 2017,
RS(11), No. 16, 2019, pp. xx-yy.
DOI Link 1909
BibRef

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New ECOSTRESS and MODIS Land Surface Temperature Data Reveal Fine-Scale Heat Vulnerability in Cities: A Case Study for Los Angeles County, California,
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Wang, H.[Han], Mao, K.[Kebiao], Mu, F.[Fengyun], Shi, J.C.[Jian-Cheng], Yang, J.[Jun], Li, Z.[Zhaoliang], Qin, Z.[Zhihao],
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He, M.[Min], Wang, D.H.[Dong-Hai], Ding, W.Y.[Wei-Yu], Wan, Y.[Yijing], Chen, Y.[Yonghang], Zhang, Y.[Yu],
A Validation of Fengyun4A Temperature and Humidity Profile Products by Radiosonde Observations,
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Wang, L.J.[Li-Juan], Guo, N.[Ni], Wang, W.[Wei], Zuo, H.C.[Hong-Chao],
Optimization of the Local Split-Window Algorithm for FY-4A Land Surface Temperature Retrieval,
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Heck, E.[Ethan], de Beurs, K.M.[Kirsten M.], Owsley, B.C.[Braden C.], Henebry, G.M.[Geoffrey M.],
Evaluation of the MODIS collections 5 and 6 for change analysis of vegetation and land surface temperature dynamics in North and South America,
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Change analysis, Western hemisphere, NDVI, EVI, LST BibRef

Sismanidis, P.[Panagiotis], Keramitsoglou, I.[Iphigenia], Barberis, S.[Stefano], Dorotic, H.[Hrvoje], Bechtel, B.[Benjamin], Kiranoudis, C.T.[Chris T.],
PLANHEAT's Satellite-Derived Heating and Cooling Degrees Dataset for Energy Demand Mapping and Planning,
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Liu, Y.L.[Yu-Ling], Yu, Y.[Yunyue], Yu, P.[Peng], Wang, H.[Heshun], Rao, Y.[Yuhan],
Enterprise LST Algorithm Development and Its Evaluation with NOAA 20 Data,
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Chu, W.T., Ho, K.C., Borji, A.,
Visual Weather Temperature Prediction,
WACV18(234-241)
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convolution, feature extraction, feedforward neural nets, geophysical image processing, image sequences, Visualization BibRef

Ikani, V., Chokmani, K., Fathollahi, L., Granberg, H., Fournier, R.,
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Chen, Z., Jiang, W.G., Tang, Z.H., Jia, K.,
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Ibrahim, I., Samah, A.A.[A. Abu], Fauzi, R., Noor, N.M.,
The Land Surface Temperature Impact To Land Cover Types,
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Balcik, F.B.[F. Bektas], Ergene, E.M.,
Determining The Impacts Of Land Cover/use Categories On Land Surface Temperature Using Landsat8-oli,
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Orhan, O., Yakar, M.,
Investigating Land Surface Temperature Changes Using Landsat Data in Konya, Turkey,
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Huang, J., Zhou, Q.,
Relations Between Grace-derived Water Storage Change With Precipitation And Temperature Over Kaidu River Basin, China,
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Nithiyanandam, Y., Nichol, J.E.,
A Simple And Effective Retrieval Of Land Surface Temperature Using A New Reflectance Based Emissivity Estimation Technique,
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Bernales, A.M., Antolihao, J.A., Samonte, C., Campomanes, F., Rojas, R.J., dela Serna, A.M., Silapan, J.,
Modelling The Relationship Between Land Surface Temperature And Landscape Patterns Of Land Use Land Cover Classification Using Multi Linear Regression Models,
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Ibitolu, H.A., Ogunjobi, K.O.,
Inter-seasonal Dynamics Of Vegetation Cover And Surface Temperature Distribution: A Case Study Of Ondo State, Nigeria,
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Zhang, J., Jung, J., Sohn, G., Cohen, M.,
Thermal Infrared Inspection of Roof Insulation Using Unmanned Aerial Vehicles,
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Cook, M.J., Schott, J.R.,
The Atmospheric Compensation Component of a Landsat Land Surface Temperature (LST) Product: Assessment of Errors Expected for a North American Test Product,
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Ding, J.F.[Ji-Feng], Zhao, J.Y.[Ji-Yin], Ma, B.[Biao],
Remote Monitoring System of Temperature and Humidity Based on GSM,
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Pan, J.[Jun], Xing, L.X.[Li-Xin], Wen, J.C.[Jiu-Cheng], Meng, T.[Tao], Jiang, L.J.[Li-Jun],
Inversion Method Study on Short Wave Infrared Remote Sensing Data High Temperature Surface Feature Temperature,
CISP09(1-4).
IEEE DOI 0910
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Zhou, L.[Li], Jiang, T.C.[Ting-Chen], Lu, X.[Xia],
A Practical Method of Feature Extraction for Water Surface Temperature Based on Thermal Infrared Remote Sensing Image,
CISP09(1-4).
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Prakash, S., Lee, P.Y.[Pei Yean], Caelli, T.M.,
3D Mapping of Surface Temperature Using Thermal Stereo,
ICARCV06(1-4).
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Chapter on Remote Sensing, Cartography, Aerial Images, Buildings, Roads, Terrain, ATR continues in
Sea Surface Temperature, SST .

Last update:Oct 1, 2019 at 15:23:24