23.2.21.3 Land Surface Temperature using MODIS

Chapter Contents (Back)
Surface Temperature. Temperature. MODIS.

Soliman, A., Duguay, C., Saunders, W., Hachem, S.,
Pan-Arctic Land Surface Temperature from MODIS and AATSR: Product Development and Intercomparison,
RS(4), No. 12, December 2012, pp. 3833-3856.
DOI Link 1211
BibRef

Williamson, S.N.[Scott N.], Hik, D.S.[David S.], Gamon, J.A.[John A.], Kavanaugh, J.L.[Jeffrey L.], Flowers, G.E.[Gwenn E.],
Estimating Temperature Fields from MODIS Land Surface Temperature and Air Temperature Observations in a Sub-Arctic Alpine Environment,
RS(6), No. 2, 2014, pp. 946-963.
DOI Link 1403
BibRef

Zhao, W.[Wei], Li, A.[Ainong], Bian, J.H.[Jin-Hu], Jin, H.[Huaan], Zhang, Z.J.[Zheng-Jian],
A Synergetic Algorithm for Mid-Morning Land Surface Soil and Vegetation Temperatures Estimation Using MSG-SEVIRI Products and TERRA-MODIS Products,
RS(6), No. 3, 2014, pp. 2213-2238.
DOI Link 1404
BibRef

Duan, S.B.[Si-Bo], Li, Z.L.[Zhao-Liang], Tang, B.H.[Bo-Hui], Wu, H.[Hua], Tang, R.L.[Rong-Lin], Bi, Y.Y.[Yu-Yun], Zhou, G.Q.[Guo-Qing],
Estimation of Diurnal Cycle of Land Surface Temperature at High Temporal and Spatial Resolution from Clear-Sky MODIS Data,
RS(6), No. 4, 2014, pp. 3247-3262.
DOI Link 1405
BibRef

Zhou, J.[Ji], Zhang, X.[Xu], Zhan, W.F.[Wen-Feng], Zhang, H.[Huailan],
Land Surface Temperature Retrieval from MODIS Data by Integrating Regression Models and the Genetic Algorithm in an Arid Region,
RS(6), No. 6, 2014, pp. 5344-5367.
DOI Link 1407
BibRef

Rhee, J.Y.[Jin-Young], Im, J.H.[Jung-Ho],
Estimating High Spatial Resolution Air Temperature for Regions with Limited in situ Data Using MODIS Products,
RS(6), No. 8, 2014, pp. 7360-7378.
DOI Link 1410
BibRef

Jang, K.[Keunchang], Kang, S.[Sinkyu], Kimball, J.S.[John S.], Hong, S.Y.[Suk Young],
Retrievals of All-Weather Daily Air Temperature Using MODIS and AMSR-E Data,
RS(6), No. 9, 2014, pp. 8387-8404.
DOI Link 1410
BibRef

Phompila, C.[Chittana], Lewis, M.[Megan], Ostendorf, B.[Bertram], Clarke, K.[Kenneth],
MODIS EVI and LST Temporal Response for Discrimination of Tropical Land Covers,
RS(7), No. 5, 2015, pp. 6026-6040.
DOI Link 1506
BibRef

Wongsai, N.[Noppachai], Wongsai, S.[Sangdao], Huete, A.R.[Alfredo R.],
Annual Seasonality Extraction Using the Cubic Spline Function and Decadal Trend in Temporal Daytime MODIS LST Data,
RS(9), No. 12, 2017, pp. xx-yy.
DOI Link 1802
BibRef

Xia, G.[Geng], Zhou, L.M.[Li-Ming],
Detecting Wind Farm Impacts on Local Vegetation Growth in Texas and Illinois Using MODIS Vegetation Greenness Measurements,
RS(9), No. 7, 2017, pp. xx-yy.
DOI Link 1708
BibRef

Yu, W.P.[Wen-Ping], Ma, M.G.[Ming-Guo], Wang, X.F.[Xu-Feng], Geng, L.Y.[Li-Ying], Tan, J.L.[Jun-Lei], Shi, J.[Jinan],
Evaluation of MODIS LST Products Using Longwave Radiation Ground Measurements in the Northern Arid Region of China,
RS(6), No. 11, 2014, pp. 11494-11517.
DOI Link 1412
BibRef

Zeng, L.L.[Ling-Lin], Wardlow, B.D.[Brian D.], Tadesse, T.[Tsegaye], Shan, J.[Jie], Hayes, M.J.[Michael J.], Li, D.R.[De-Ren], Xiang, D.X.[Da-Xiang],
Estimation of Daily Air Temperature Based on MODIS Land Surface Temperature Products over the Corn Belt in the US,
RS(7), No. 1, 2015, pp. 951-970.
DOI Link 1502
BibRef

Huang, R.[Ran], Zhang, C.[Chao], Huang, J.X.[Jian-Xi], Zhu, D.[Dehai], Wang, L.M.[Li-Min], Liu, J.[Jia],
Mapping of Daily Mean Air Temperature in Agricultural Regions Using Daytime and Nighttime Land Surface Temperatures Derived from TERRA and AQUA MODIS Data,
RS(7), No. 7, 2015, pp. 8728.
DOI Link 1506
BibRef

Yang, G.J.[Gui-Jun], Weng, Q.H.[Qi-Hao], Pu, R.L.[Rui-Liang], Gao, F.[Feng], Sun, C.H.[Chen-Hong], Li, H.[Hua], Zhao, C.J.[Chun-Jiang],
Evaluation of ASTER-Like Daily Land Surface Temperature by Fusing ASTER and MODIS Data during the HiWATER-MUSOEXE,
RS(8), No. 1, 2016, pp. 75.
DOI Link 1602
BibRef

Kou, X.K.[Xiao-Kang], Jiang, L.[Lingmei], Bo, Y.C.[Yan-Chen], Yan, S.[Shuang], Chai, L.[Linna],
Estimation of Land Surface Temperature through Blending MODIS and AMSR-E Data with the Bayesian Maximum Entropy Method,
RS(8), No. 2, 2016, pp. 105.
DOI Link 1603
BibRef

Zhou, S.G.[Shu-Gui], Cheng, J.[Jie],
A Framework for Estimating Clear-Sky Atmospheric Total Precipitable Water (TPW) from VIIRS/S-NPP,
RS(11), No. 8, 2019, pp. xx-yy.
DOI Link 1905
BibRef

Tang, B.H., Wang, J.,
A Physics-Based Method to Retrieve Land Surface Temperature From MODIS Daytime Midinfrared Data,
GeoRS(54), No. 8, August 2016, pp. 4672-4679.
IEEE DOI 1608
atmospheric humidity BibRef

Lin, X.H.[Xiao-Hui], Zhang, W.[Wen], Huang, Y.[Yao], Sun, W.J.[Wen-Juan], Han, P.F.[Peng-Fei], Yu, L.F.[Ling-Fei], Sun, F.F.[Fei-Fei],
Empirical Estimation of Near-Surface Air Temperature in China from MODIS LST Data by Considering Physiographic Features,
RS(8), No. 8, 2016, pp. 629.
DOI Link 1609
BibRef

Laskin, D.N.[David N.], Montaghi, A.[Alessandro], Nielsen, S.E.[Scott E.], McDermid, G.J.[Gregory J.],
Estimating Understory Temperatures Using MODIS LST in Mixed Cordilleran Forests,
RS(8), No. 8, 2016, pp. 658.
DOI Link 1609
BibRef

Duan, S.B., Li, Z.L.,
Spatial Downscaling of MODIS Land Surface Temperatures Using Geographically Weighted Regression: Case Study in Northern China,
GeoRS(54), No. 11, November 2016, pp. 6458-6469.
IEEE DOI 1610
Algorithm design and analysis BibRef

Meyer, H.[Hanna], Katurji, M.[Marwan], Appelhans, T.[Tim], Müller, M.U.[Markus U.], Nauss, T.[Thomas], Roudier, P.[Pierre], Zawar-Reza, P.[Peyman],
Mapping Daily Air Temperature for Antarctica Based on MODIS LST,
RS(8), No. 9, 2016, pp. 732.
DOI Link 1610
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

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

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

Loveless, M.[Michelle], Borbas, E.E.[E. Eva], Knuteson, R.[Robert], Cawse-Nicholson, K.[Kerry], Hulley, G.[Glynn], Hook, S.[Simon],
Climatology of the Combined ASTER MODIS Emissivity over Land (CAMEL) Version 2,
RS(13), No. 1, 2021, pp. xx-yy.
DOI Link 2101
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

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

Cai, Y.L.[Yu-Lin], Chen, G.[Gang], Wang, Y.L.[Ya-Li], 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

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

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

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

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

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

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

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

Kang, J.[Jian], Tan, J.L.[Jun-Lei], 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

Lu, L.[Lei], Zhang, T.J.[Ting-Jun], 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

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

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

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.F.[Gao-Fei], 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

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

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

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

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

Sun, D.L.[Dong-Lian], Li, Y.[Yu], Zhan, X.[Xiwu], Houser, P.[Paul], Yang, C.W.[Chao-Wei], 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

Hulley, G.[Glynn], Shivers, S.[Sarah], Wetherley, E.[Erin], Cudd, R.[Robert],
New ECOSTRESS and MODIS Land Surface Temperature Data Reveal Fine-Scale Heat Vulnerability in Cities: A Case Study for Los Angeles County, California,
RS(11), No. 18, 2019, pp. xx-yy.
DOI Link 1909
BibRef

Ruiz-Álvarez, M.[Marcos], Alonso-Sarria, F.[Francisco], Gomariz-Castillo, F.[Francisco],
Interpolation of Instantaneous Air Temperature Using Geographical and MODIS Derived Variables with Machine Learning Techniques,
IJGI(8), No. 9, 2019, pp. xx-yy.
DOI Link 1909
BibRef

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,
PandRS(156), 2019, pp. 121-134.
Elsevier DOI 1909
Change analysis, Western hemisphere, NDVI, EVI, LST BibRef

Li, H., Yang, Y., Li, R., Wang, H., Cao, B., Bian, Z., Hu, T., Du, Y., Sun, L., Liu, Q.,
Comparison of the MuSyQ and MODIS Collection 6 Land Surface Temperature Products Over Barren Surfaces in the Heihe River Basin, China,
GeoRS(57), No. 10, October 2019, pp. 8081-8094.
IEEE DOI 1910
atmospheric techniques, emissivity, land surface temperature, mean square error methods, radiometry, remote sensing, rivers, soil, split-window (SW) algorithm BibRef

El Kenawy, A.M.[Ahmed M.], Hereher, M.E.[Mohamed E.], Robaa, S.M.[Sayed M.],
An Assessment of the Accuracy of MODIS Land Surface Temperature over Egypt Using Ground-Based Measurements,
RS(11), No. 20, 2019, pp. xx-yy.
DOI Link 1910
BibRef

Otgonbayar, M.[Munkhdulam], Atzberger, C.[Clement], Mattiuzzi, M.[Matteo], Erdenedalai, A.[Avirmed],
Estimation of Climatologies of Average Monthly Air Temperature over Mongolia Using MODIS Land Surface Temperature (LST) Time Series and Machine Learning Techniques,
RS(11), No. 21, 2019, pp. xx-yy.
DOI Link 1911
BibRef

Chang, Y.P.[Ya-Ping], Ding, Y.J.[Yong-Jian], Zhao, Q.[Qiudong], Zhang, S.Q.[Shi-Qiang],
A Comprehensive Evaluation of 4-Parameter Diurnal Temperature Cycle Models with In Situ and MODIS LST over Alpine Meadows in the Tibetan Plateau,
RS(12), No. 1, 2019, pp. xx-yy.
DOI Link 2001
BibRef

Liu, H.Z.[Heng-Zi], Lu, N.[Ning], Jiang, H.[Hou], Qin, J.[Jun], Yao, L.[Ling],
Filling Gaps of Monthly Terra/MODIS Daytime Land Surface Temperature Using Discrete Cosine Transform Method,
RS(12), No. 3, 2020, pp. xx-yy.
DOI Link 2002
BibRef

Qie, Y.F.[Yu-Fan], Wang, N.L.[Ning-Lian], Wu, Y.W.[Yu-Wei], Chen, A.[An'an],
Variations in Winter Surface Temperature of the Purog Kangri Ice Field, Qinghai-Tibetan Plateau, 2001-2018, Using MODIS Data,
RS(12), No. 7, 2020, pp. xx-yy.
DOI Link 2004
BibRef

Yoo, C.[Cheolhee], Im, J.[Jungho], Cho, D.J.[Dong-Jin], Yokoya, N.[Naoto], Xia, J.[Junshi], Bechtel, B.[Benjamin],
Estimation of All-Weather 1 km MODIS Land Surface Temperature for Humid Summer Days,
RS(12), No. 9, 2020, pp. xx-yy.
DOI Link 2005
BibRef

Sánchez, J.M.[Juan M.], Galve, J.M.[Joan M.], González-Piqueras, J.[José], López-Urrea, R.[Ramón], Niclňs, R.[Raquel], Calera, A.[Alfonso],
Monitoring 10-m LST from the Combination MODIS/Sentinel-2, Validation in a High Contrast Semi-Arid Agroecosystem,
RS(12), No. 9, 2020, pp. xx-yy.
DOI Link 2005
BibRef

Sunder, S.[Swathy], Ramsankaran, R.[RAAJ], Ramakrishnan, B.[Balaji],
Machine learning techniques for regional scale estimation of high-resolution cloud-free daily sea surface temperatures from MODIS data,
PandRS(166), 2020, pp. 228-240.
Elsevier DOI 2007
cloud-free SST, SVR, ANN, RF, MODIS BibRef

Hu, L.Q.[Lei-Qiu], Sun, Y.[Ying], Collins, G.[Gavin], Fu, P.[Peng],
Improved estimates of monthly land surface temperature from MODIS using a diurnal temperature cycle (DTC) model,
PandRS(168), 2020, pp. 131 - 140.
Elsevier DOI 2009
BibRef
And: Corrigendum: PandRS(171), 2021, pp. 118.
Elsevier DOI 2012
Monthly land surface temperature, Diurnal temperature cycle model, Thermal anomalies, Droughts, MODIS BibRef

Chung, J.[Jeehun], Lee, Y.G.[Yong-Gwan], Jang, W.J.[Won-Jin], Lee, S.[Siwoon], Kim, S.[Seongjoon],
Correlation Analysis between Air Temperature and MODIS Land Surface Temperature and Prediction of Air Temperature Using TensorFlow Long Short-Term Memory for the Period of Occurrence of Cold and Heat Waves,
RS(12), No. 19, 2020, pp. xx-yy.
DOI Link 2010
BibRef

Morin, G.[Gwenaël], Le Roux, R.[Renan], Lemasle, P.G.[Pierre-Gilles], Quénol, H.[Hervé],
Mapping Bioclimatic Indices by Downscaling MODIS Land Surface Temperature: Case Study of the Saint-Emilion Area,
RS(13), No. 1, 2021, pp. xx-yy.
DOI Link 2101
BibRef

Liu, J.[Jiang], Hagan, D.F.T.[Daniel Fiifi Tawia], Liu, Y.[Yi],
Global Land Surface Temperature Change (2003-2017) and Its Relationship with Climate Drivers: AIRS, MODIS, and ERA5-Land Based Analysis,
RS(13), No. 1, 2021, pp. xx-yy.
DOI Link 2101
BibRef

Tan, J.L.[Jun-Lei], Che, T.[Tao], Wang, J.[Jian], Liang, J.[Ji], Zhang, Y.[Yang], Ren, Z.G.[Zhi-Guo],
Reconstruction of the Daily MODIS Land Surface Temperature Product Using the Two-Step Improved Similar Pixels Method,
RS(13), No. 9, 2021, pp. xx-yy.
DOI Link 2105
BibRef

Xiao, Y.[Yao], Zhao, W.[Wei], Ma, M.G.[Ming-Guo], He, K.L.[Kun-Long],
Gap-Free LST Generation for MODIS/Terra LST Product Using a Random Forest-Based Reconstruction Method,
RS(13), No. 14, 2021, pp. xx-yy.
DOI Link 2107
BibRef

Xing, Z.F.[Ze-Feng], Li, Z.L.[Zhao-Liang], Duan, S.B.[Si-Bo], Liu, X.Y.[Xiang-Yang], Zheng, X.[Xiaopo], Leng, P.[Pei], Gao, M.[Maofang], Zhang, X.[Xia], Shang, G.F.[Guo-Fei],
Estimation of daily mean land surface temperature at global scale using pairs of daytime and nighttime MODIS instantaneous observations,
PandRS(178), 2021, pp. 51-67.
Elsevier DOI 2108
Land surface temperature, Daily mean temperature, MODIS BibRef

Reiners, P.[Philipp], Asam, S.[Sarah], Frey, C.[Corinne], Holzwarth, S.[Stefanie], Bachmann, M.[Martin], Sobrino, J.[Jose], Göttsche, F.M.[Frank-M.], Bendix, J.[Jörg], Kuenzer, C.[Claudia],
Validation of AVHRR Land Surface Temperature with MODIS and In Situ LST: A TIMELINE Thematic Processor,
RS(13), No. 17, 2021, pp. xx-yy.
DOI Link 2109
BibRef

Zhao, X.Y.[Xiao-Yang], Xia, H.M.[Hao-Ming], Pan, L.[Li], Song, H.Q.[Hong-Quan], Niu, W.H.[Wen-Hui], Wang, R.M.[Rui-Meng], Li, R.M.[Ru-Meng], Bian, X.Q.[Xi-Qing], Guo, Y.[Yan], Qin, Y.C.[Yao-Chen],
Drought Monitoring over Yellow River Basin from 2003-2019 Using Reconstructed MODIS Land Surface Temperature in Google Earth Engine,
RS(13), No. 18, 2021, pp. xx-yy.
DOI Link 2109
BibRef

Guo, D.F.[Dian-Fan], Wang, C.Z.[Cui-Zhen], Zang, S.Y.[Shu-Ying], Hua, J.X.[Jin-Xi], Lv, Z.H.[Zheng-Han], Lin, Y.[Yue],
Gap-Filling of 8-Day Terra MODIS Daytime Land Surface Temperature in High-Latitude Cold Region with Generalized Additive Models (GAM),
RS(13), No. 18, 2021, pp. xx-yy.
DOI Link 2109
BibRef

Valdes, L.M.L.[Lilian-Maite Lezama], Katurji, M.[Marwan], Meyer, H.[Hanna],
A Machine Learning Based Downscaling Approach to Produce High Spatio-Temporal Resolution Land Surface Temperature of the Antarctic Dry Valleys from MODIS Data,
RS(13), No. 22, 2021, pp. xx-yy.
DOI Link 2112
BibRef

Yao, R.[Rui], Wang, L.[Lunche], Huang, X.[Xin], Sun, L.[Liang], Chen, R.Q.[Rui-Qing], Wu, X.J.[Xiao-Jun], Zhang, W.[Wei], Niu, Z.[Zigeng],
A Robust Method for Filling the Gaps in MODIS and VIIRS Land Surface Temperature Data,
GeoRS(59), No. 12, December 2021, pp. 10738-10752.
IEEE DOI 2112
Land surface temperature, Spatiotemporal phenomena, Clouds, Land surface, Temperature sensors, MODIS, Remote sensing, China, interpolation BibRef

Tan, W.W.[Wei-Wei], Wei, C.Z.[Chun-Zhu], Lu, Y.[Yang], Xue, D.S.[De-Sheng],
Reconstruction of All-Weather Daytime and Nighttime MODIS Aqua-Terra Land Surface Temperature Products Using an XGBoost Approach,
RS(13), No. 22, 2021, pp. xx-yy.
DOI Link 2112
BibRef

Cui, J.Y.[Jian-Yong], Zhang, M.[Manyu], Song, D.M.[Dong-Mei], Shan, X.J.[Xin-Jian], Wang, B.[Bin],
MODIS Land Surface Temperature Product Reconstruction Based on the SSA-BiLSTM Model,
RS(14), No. 4, 2022, pp. xx-yy.
DOI Link 2202
BibRef

Cho, D.J.[Dong-Jin], Bae, D.[Dukwon], Yoo, C.[Cheolhee], Im, J.[Jungho], Lee, Y.[Yeonsu], Lee, S.[Siwoo],
All-Sky 1 km MODIS Land Surface Temperature Reconstruction Considering Cloud Effects Based on Machine Learning,
RS(14), No. 8, 2022, pp. xx-yy.
DOI Link 2205
BibRef

Wang, C.L.[Chun-Ling], Bi, X.[Xu], Luan, Q.Z.[Qing-Zu], Li, Z.Q.[Zhan-Qing],
Estimation of Daily and Instantaneous Near-Surface Air Temperature from MODIS Data Using Machine Learning Methods in the Jingjinji Area of China,
RS(14), No. 8, 2022, pp. xx-yy.
DOI Link 2205
BibRef

Agathangelidis, I.[Ilias], Cartalis, C.[Constantinos], Polydoros, A.[Anastasios], Mavrakou, T.[Thaleia], Philippopoulos, K.[Kostas],
Can Satellite-Based Thermal Anomalies Be Indicative of Heatwaves? An Investigation for MODIS Land Surface Temperatures in the Mediterranean Region,
RS(14), No. 13, 2022, pp. xx-yy.
DOI Link 2208
BibRef

Recondo, C.[Carmen], Corbea-Pérez, A.[Alejandro], Peón, J.[Juanjo], Pendás, E.[Enrique], Ramos, M.[Miguel], Calleja, J.F.[Javier F.], de Pablo, M.Á.[Miguel Ángel], Fernández, S.[Susana], Corrales, J.A.[José Antonio],
Empirical Models for Estimating Air Temperature Using MODIS Land Surface Temperature (and Spatiotemporal Variables) in the Hurd Peninsula of Livingston Island, Antarctica, between 2000 and 2016,
RS(14), No. 13, 2022, pp. xx-yy.
DOI Link 2208
BibRef

Wang, J.R.[Jun-Rui], Tang, R.L.[Rong-Lin], Jiang, Y.Z.[Ya-Zhen], Liu, M.[Meng], Li, Z.L.[Zhao-Liang],
A practical method for angular normalization of global MODIS land surface temperature over vegetated surfaces,
PandRS(199), 2023, pp. 289-304.
Elsevier DOI 2305
Land surface temperature, MODIS, Angular anisotropy, Angular normalization BibRef

Xie, A.[Aihong], Zhu, J.P.[Jiang-Ping], Qin, X.[Xiang], Wang, S.[Shimeng],
The Antarctic Amplification Based on MODIS Land Surface Temperature and ERA5,
RS(15), No. 14, 2023, pp. 3540.
DOI Link 2307
BibRef

Jiang, Y.P.[Yue-Peng], Cao, Y.[Yunhua], Wu, Z.S.[Zhen-Sen], Cao, Y.[Yisen],
Validation of MODIS Temperature and Emissivity Products Based on Ground-Based Mid-Wave Hyperspectral Imaging Measurement in the Northwestern Plateau Region of Qinghai, China,
RS(15), No. 15, 2023, pp. xx-yy.
DOI Link 2308
BibRef


Chapter on Remote Sensing General Issue, Land Use, Land Cover continues in
Atmospheric Temperature, Atmospheric Analysis .


Last update:Mar 16, 2024 at 20:36:19