9.1.3.1 Land Surface Albedo

Chapter Contents (Back)
Surface Albedo. Albedo. General Albedo computation:
See also Reflectance Computations, Albedo.
See also Land Surface Temperature, Remote Sensing.

Hu, B.X.[Bao-Xin], Lucht, W.[Wolfgang], Strahler, A.H.[Alan H.], Schaaf, C.B.[Crystal Barker], Smith, M.[Milton],
Surface Albedos and Angle-Corrected NDVI from AVHRR Observations of South America,
RSE(71), No. 2, 2000, pp. 119-132. 0002
BibRef

Lyapustin, A.I.,
Three-dimensional effects in the remote sensing of surface albedo,
GeoRS(39), No. 2, February 2001, pp. 254-263.
IEEE Top Reference. 0104
BibRef

Pokrovsky, O.[Oleg], Roujean, J.L.[Jean-Louis],
Land surface albedo retrieval via kernel-based BRDF modeling: I. Statistical inversion method and model comparison,
RSE(84), No. 1, January 2003, pp. 100-119.
HTML Version. 0211
BibRef

Pokrovsky, O.[Oleg], Roujean, J.L.[Jean-Louis],
Land surface albedo retrieval via kernel-based BRDF modeling: II. An optimal design scheme for the angular sampling,
RSE(84), No. 1, January 2003, pp. 120-142.
HTML Version. 0211
BibRef

Geiger, B., Carrer, D., Franchistéguy, L., Roujean, J.L., Meurey, C.,
Land Surface Albedo Derived on a Daily Basis From Meteosat Second Generation Observations,
GeoRS(46), No. 11, November 2008, pp. 3841-3856.
IEEE DOI 0812
BibRef

Carrer, D., Roujean, J.L., Meurey, C.,
Comparing Operational MSG/SEVIRI Land Surface Albedo Products From Land SAF With Ground Measurements and MODIS,
GeoRS(48), No. 4, April 2010, pp. 1714-1728.
IEEE DOI 1003
BibRef

Gao, B.[Bo], Jia, L.[Li], Wang, T.X.[Tian-Xing],
Derivation of Land Surface Albedo at High Resolution by Combining HJ-1A/B Reflectance Observations with MODIS BRDF Products,
RS(6), No. 9, 2014, pp. 8966-8985.
DOI Link 1410
BibRef

Franch, B., Vermote, E.F., Sobrino, J.A., Julien, Y.,
Retrieval of Surface Albedo on a Daily Basis: Application to MODIS Data,
GeoRS(52), No. 12, December 2014, pp. 7549-7558.
IEEE DOI 1410
albedo BibRef

Gao, B.[Bo], Gong, H.[Huili], Wang, T.X.[Tian-Xing],
A Method for Retrieving Daily Land Surface Albedo from Space at 30-m Resolution,
RS(7), No. 8, 2015, pp. 10951.
DOI Link 1509
BibRef

Gao, B.[Bo], Gong, H.[Huili], Wang, T.X.[Tian-Xing], Jia, L.[Li],
Reconstruction of MODIS Spectral Reflectance under Cloudy-Sky Condition,
RS(8), No. 9, 2016, pp. 727.
DOI Link 1610
BibRef

He, T.[Tao], Liang, S.L.[Shun-Lin], Wang, D.D.[Dong-Dong], Chen, X.N.[Xiao-Na], Song, D.X.[Dan-Xia], Jiang, B.[Bo],
Land Surface Albedo Estimation from Chinese HJ Satellite Data Based on the Direct Estimation Approach,
RS(7), No. 5, 2015, pp. 5495-5510.
DOI Link 1506
BibRef

Benas, N.[Nikolaos], Chrysoulakis, N.[Nektarios],
Estimation of the Land Surface Albedo Changes in the Broader Mediterranean Area, Based on 12 Years of Satellite Observations,
RS(7), No. 12, 2015, pp. 15816.
DOI Link 1601
BibRef

He, T.[Tao], Liang, S.L.[Shun-Lin], Wang, D.D.[Dong-Dong],
Direct Estimation of Land Surface Albedo From Simultaneous MISR Data,
GeoRS(55), No. 5, May 2017, pp. 2605-2617.
IEEE DOI 1609
albedo, atmospheric optics, radiometry, reflectivity, remote sensing, AmeriFlux site, MISR instrument, MISR product, aerosol estimation, albedo accuracy, albedo algorithm, cloud masking, direct land surface albedo estimation, gap-free clear-sky surface albedo estimation, multiangle imaging spectroradiometer, multiangular information, optical sensor, simultaneous MISR data, surface anisotropy characterization, surface reflectance, top-of-atmosphere reflectance, Atmospheric modeling, bidirectional reflectance distribution function (BRDF),
See also Estimating Top-of-Atmosphere Daily Reflected Shortwave Radiation Flux Over Land From MODIS Data. BibRef

Carrer, D.[Dominique], Moparthy, S.[Suman], Lellouch, G.[Gabriel], Ceamanos, X.[Xavier], Pinault, F.[Florian], Freitas, S.C.[Sandra C.], Trigo, I.F.[Isabel F.],
Land Surface Albedo Derived on a Ten Daily Basis from Meteosat Second Generation Observations: The NRT and Climate Data Record Collections from the EUMETSAT LSA SAF,
RS(10), No. 8, 2018, pp. xx-yy.
DOI Link 1809
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Zhang, G.D.[Guo-Dong], Zhou, H.M.[Hong-Min], Wang, C.J.[Chang-Jing], Xue, H.Z.[Hua-Zhu], Wang, J.D.[Jin-Di], Wan, H.[Huawei],
Time Series High-Resolution Land Surface Albedo Estimation Based on the Ensemble Kalman Filter Algorithm,
RS(11), No. 7, 2019, pp. xx-yy.
DOI Link 1904
BibRef

He, T.[Tao], Zhang, Y.[Yi], Liang, S.L.[Shun-Lin], Yu, Y.Y.[Yun-Yue], Wang, D.D.[Dong-Dong],
Developing Land Surface Directional Reflectance and Albedo Products from Geostationary GOES-R and Himawari Data: Theoretical Basis, Operational Implementation, and Validation,
RS(11), No. 22, 2019, pp. xx-yy.
DOI Link 1911
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Xiao, Z.Q.[Zhi-Qiang], Liang, S.L.[Shun-Lin], Wang, J.[Jindi], Xie, D.H.[Dong-Hui], Song, J.L.[Jin-Ling], Fensholt, R.,
A Framework for Consistent Estimation of Leaf Area Index, Fraction of Absorbed Photosynthetically Active Radiation, and Surface Albedo from MODIS Time-Series Data,
GeoRS(53), No. 6, June 2015, pp. 3178-3197.
IEEE DOI 1503
albedo
See also Retrieval of Leaf Area Index (LAI) and Fraction of Absorbed Photosynthetically Active Radiation (FAPAR) from VIIRS Time-Series Data. BibRef

Sánchez-Zapero, J.[Jorge], Camacho, F.[Fernando], Martínez-Sánchez, E.[Enrique], Lacaze, R.[Roselyne], Carrer, D.[Dominique], Pinault, F.[Florian], Benhadj, I.[Iskander], Muñoz-Sabater, J.[Joaquín],
Quality Assessment of PROBA-V Surface Albedo V1 for the Continuity of the Copernicus Climate Change Service,
RS(12), No. 16, 2020, pp. xx-yy.
DOI Link 2008
BibRef

Zhou, Y.[Yuan], Wang, D.D.[Dong-Dong], Liang, S.L.[Shun-Lin], Yu, Y.[Yunyue], He, T.[Tao],
Assessment of the Suomi NPP VIIRS Land Surface Albedo Data Using Station Measurements and High-Resolution Albedo Maps,
RS(8), No. 2, 2016, pp. 137.
DOI Link 1603
BibRef

Liu, Y.L.[Yu-Ling], Yu, P.[Peng], Wang, H.[Heshun], Peng, J.J.[Jing-Jing], Yu, Y.[Yunyue],
Ten Years of VIIRS Land Surface Temperature Product Validation,
RS(14), No. 12, 2022, pp. xx-yy.
DOI Link 2206
BibRef

Liu, Y.L.[Yu-Ling], Yu, Y.[Yunyue], Yu, P.[Peng], Göttsche, F.M.[Frank M.], Trigo, I.F.[Isabel F.],
Quality Assessment of S-NPP VIIRS Land Surface Temperature Product,
RS(7), No. 9, 2015, pp. 12215.
DOI Link 1511
BibRef

Wang, D.D.[Dong-Dong], Liang, S.L.[Shun-Lin], Zhou, Y.[Yuan], He, T.[Tao], Yu, Y.[Yunyue],
A New Method for Retrieving Daily Land Surface Albedo From VIIRS Data,
GeoRS(55), No. 3, March 2017, pp. 1765-1775.
IEEE DOI 1703
Aerosols BibRef

He, T.[Tao], Liang, S.L.[Shun-Lin], Wang, D.D.[Dong-Dong], Shuai, Y., Yu, Y.[Yunyue],
Fusion of Satellite Land Surface Albedo Products Across Scales Using a Multiresolution Tree Method in the North Central United States,
GeoRS(52), No. 6, June 2014, pp. 3428-3439.
IEEE DOI 1403
Clouds BibRef

Riihelä, A.[Aku], Manninen, T.[Terhikki], Key, J.[Jeffrey], Sun, Q.S.[Qing-Song], Sütterlin, M.[Melanie], Lattanzio, A.[Alessio], Schaaf, C.[Crystal],
A Multisensor Approach to Global Retrievals of Land Surface Albedo,
RS(10), No. 6, 2018, pp. xx-yy.
DOI Link 1806
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Tian, Q.Y.[Qiu-Yue], Liu, Q.A.[Qi-Ang], Guang, J.[Jie], Yang, L.[Leiku], Zhang, H.W.[Han-Wei], Fan, C.[Cheng], Che, Y.H.[Ya-Hui], Li, Z.Q.[Zheng-Qiang],
The Estimation of Surface Albedo from DSCOVR EPIC,
RS(12), No. 11, 2020, pp. xx-yy.
DOI Link 2006
BibRef

Lellouch, G.[Gabriel], Carrer, D.[Dominique], Vincent, C.[Chloé], Pardé, M.[Mickael], Frietas, S.C.[Sandra C.], Trigo, I.F.[Isabel F.],
Evaluation of Two Global Land Surface Albedo Datasets Distributed by the Copernicus Climate Change Service and the EUMETSAT LSA-SAF,
RS(12), No. 11, 2020, pp. xx-yy.
DOI Link 2006
BibRef

Lin, X.W.[Xing-Wen], Wen, J.G.[Jian-Guang], Liu, Q.H.[Qin-Huo], You, D.Q.[Dong-Qin], Wu, S.B.[Sheng-Biao], Hao, D.L.[Da-Lei], Xiao, Q.[Qing], Zhang, Z.Y.[Zhao-Yang], Zhang, Z.Z.[Zhen-Zhen],
Spatiotemporal Variability of Land Surface Albedo over the Tibet Plateau from 2001 to 2019,
RS(12), No. 7, 2020, pp. xx-yy.
DOI Link 2004
BibRef

Wang, M.S.[Meng-Si], Fan, X.L.[Xian-Lei], Li, X.J.[Xi-Jia], Liu, Q.A.[Qi-Ang], Qu, Y.[Ying],
Estimation of Land Surface Albedo from MODIS and VIIRS Data: A Multi-Sensor Strategy Based on the Direct Estimation Algorithm and Statistical-Based Temporal Filter,
RS(12), No. 24, 2020, pp. xx-yy.
DOI Link 2012
BibRef

Carrer, D.[Dominique], Pinault, F.[Florian], Lellouch, G.[Gabriel], Trigo, I.F.[Isabel F.], Benhadj, I.[Iskander], Camacho, F.[Fernando], Ceamanos, X.[Xavier], Moparthy, S.[Suman], Munoz-Sabater, J.[Joaquin], Schüller, L.[Lothar], Sánchez-Zapero, J.[Jorge],
Surface Albedo Retrieval from 40-Years of Earth Observations through the EUMETSAT/LSA SAF and EU/C3S Programmes: The Versatile Algorithm of PYALUS,
RS(13), No. 3, 2021, pp. xx-yy.
DOI Link 2102
BibRef

Lattanzio, A.[Alessio], Grant, M.[Michael], Doutriaux-Boucher, M.[Marie], Roebeling, R.[Rob], Schulz, J.[Jörg],
Assessment of the EUMETSAT Multi Decadal Land Surface Albedo Data Record from Meteosat Observations,
RS(13), No. 10, 2021, pp. xx-yy.
DOI Link 2105
BibRef

Chen, C.[Chaonan], Tian, L.[Li], Zhu, L.[Lianqi], Zhou, Y.[Yuanke],
The Impact of Climate Change on the Surface Albedo over the Qinghai-Tibet Plateau,
RS(13), No. 12, 2021, pp. xx-yy.
DOI Link 2106
BibRef

Zhang, X.N.[Xiao-Ning], Jiao, Z.[Ziti], Zhao, C.S.[Chang-Sen], Qu, Y.[Ying], Liu, Q.[Qiang], Zhang, H.[Hu], Tong, Y.D.[Yi-Dong], Wang, C.X.[Chen-Xia], Li, S.J.[Si-Jie], Guo, J.[Jing], Zhu, Z.D.[Zi-Dong], Yin, S.[Siyang], Cui, L.[Lei],
Review of Land Surface Albedo: Variance Characteristics, Climate Effect and Management Strategy,
RS(14), No. 6, 2022, pp. xx-yy.
DOI Link 2204
BibRef

Yang, J.[Jian], Shuai, Y.M.[Yan-Min], Duan, J.[Junbo], Xie, D.H.[Dong-Hui], Zhang, Q.L.[Qing-Ling], Zhao, R.[Ruishan],
Impact of BRDF Spatiotemporal Smoothing on Land Surface Albedo Estimation,
RS(14), No. 9, 2022, pp. xx-yy.
DOI Link 2205
BibRef

Zilber, D.[Daniel], Thompson, D.R.[David R.], Katzfuss, M.[Matthias], Natraj, V.[Vijay], Hobbs, J.[Jonathan], Braverman, A.[Amy],
Spatial Surface Reflectance Retrievals for Visible/Shortwave Infrared Remote Sensing via Gaussian Process Priors,
RS(14), No. 9, 2022, pp. xx-yy.
DOI Link 2205
BibRef

Ma, J.[Jie], Wen, X.H.[Xiao-Hang], Li, M.S.[Mao-Shan], Luo, S.Q.[Si-Qiong], Zhu, X.[Xian], Yang, X.Y.[Xian-Yu], Chen, M.[Mei],
Analysis of Surface Energy Changes over Different Underlying Surfaces Based on MODIS Land-Use Data and Green Vegetation Fraction over the Tibetan Plateau,
RS(14), No. 12, 2022, pp. xx-yy.
DOI Link 2206
BibRef


Chapter on 3-D Shape from X -- Shading, Textures, Lasers, Structured Light, Focus, Line Drawings continues in
Translucent Surfaces, Translucent Materials, Translucency Analysis .


Last update:Nov 28, 2022 at 16:32:47