101 research outputs found
An evaluation of SMOS L-band vegetation optical depth (L-VOD) data sets:high sensitivity of L-VOD to above-ground biomass in Africa
The vegetation optical depth (VOD) measured at microwave frequencies is related to the vegetation water content and provides information complementary to visible/infrared vegetation indices. This study is devoted to the characterization of a new VOD data set obtained from SMOS (Soil Moisture and Ocean Salinity) satellite observations at L-band (1.4 GHz). Three different SMOS L-band VOD (LVOD) data sets (SMOS level 2, level 3 and SMOS-IC) were compared with data sets on tree height, visible/infrared indexes (NDVI, EVI), mean annual precipitation and above-ground biomass (AGB) for the African continent. For all relationships, SMOS-IC showed the lowest dispersion and highest correlation. Overall, we found a strong (R > 0.85) correlation with no clear sign of saturation between L-VOD and four AGB data sets. The relationships between L-VOD and the AGB data sets were linear per land cover class but with a changing slope depending on the class type, which makes it a global non-linear relationship. In contrast, the relationship linking L-VOD to tree height (R = 0.87) was close to linear. For vegetation classes other than evergreen broadleaf forest, the annual mean of L-VOD spans a range from 0 to 0.7 and it is linearly correlated with the average annual precipitation. SMOS L-VOD showed higher sensitivity to AGB compared to NDVI and K/X/C-VOD (VOD measured at 19, 10.7 and 6.9 GHz). The results showed that, although the spatial resolution of L-VOD is coarse (similar to 40 km), the high temporal frequency and sensitivity to AGB makes SMOS L-VOD a very promising indicator for large-scale monitoring of the vegetation status, in particular biomass
Ăvaluation Ă l'Ă©chelle globale d'une variable hydrologique mesurĂ©e par tĂ©lĂ©dĂ©tection : les produits d'humiditĂ© du sol du satellite SMOS
Soil moisture (SM) plays a key role in meteorology, hydrology, and ecology as it controls the evolution of various hydrological and energy balance processes. The community of scientists involved in the field of microwave remote sensing has made considerable efforts to build accurate estimates of surface SM (SSM), and global SSM datasets derived from active and passive microwave instruments have recently become available. Among them, SMOS (Soil Moisture and Ocean Salinity), launched in 2009, was the first ever passive satellite specifically designed to measure the SSM, at L-band (1.4 GHz), at the global scale. Validation of the SMOS SSM datasets over different climatic regions and environmental conditions is extremely important and a necessary step before they can be used. A better knowledge of the skill and uncertainties of the SSM retrievals will help not only to improve the individual products, but also to optimize the fusion schemes required to create long-term multi-sensor products, like the essential climate variable (ECV) SSM product generated within the European Space Agencyâs (ESA's) Climate Change Initiative (CCI) program. After the introductory Chapters I to III, this dissertation consists of three main parts. Chap. IV of the dissertation evaluates the passive SMOS level 3 (SMOSL3) SSM products at L-band against the passive AMSR-E SSM at C-band by comparing them with a Land Data Assimilation System estimates (SM-DAS-2) produced by the European Centre for Medium Range Weather Forecasts (ECMWF). This was achieved over the common period 2010-2011 between SMOS and AMSR-E, using classical metrics (Correlation, RMSD, and Bias). In parallel, Chap. V of the dissertation evaluates the passive SMOSL3 products against the active ASCAT SSM at C-band by comparing them with land surface model simulations (MERRA-Land) using classical metrics, advanced statistical methods (triple collocation), and the Hovmöller diagram over the period 2010-2012. These two evaluations indicated that vegetation density (parameterized here by the leaf area index LAI) is a key factor to interpret the consistency between SMOS and the other remotely sensed products. This effect of the vegetation has been quantified for the first time at the global scale for the three microwave sensors. These two chapters also showed that both SMOS and ASCAT (AMSR-E) had complementary performances and, thus, have a potential for datasets fusion into long-term SSM records. In Chap. VI of the dissertation, with the general purpose to extend back the SMOSL3 SSM time series and to produce an homogeneous SM product over 2003-2014 based on SMOS and AMSR-E, we investigated the use of a multiple linear regression model based on bi-polarization (horizontal and vertical) brightness temperatures (TB) observations obtained from AMSR-E (2003 - 2011). The regression coefficients were calibrated using SMOSL3 SSM as a reference over the 2010-2011 period. The resulting merged SSM dataset was evaluated against an AMSR-E SSM retrievals and modelled SSM products (MERRA-Land) over 2007-2009. These first results show that the multi-linear regression method is a robust and simple approach to produce a realistic SSM product in terms of temporal variation and absolute values. In conclusion, this PhD showed that the potential synergy between the passive (AMSR-E and SMOS) and active (ASCAT) microwave systems at global scale is very promising for the development of improved, long-term SSM time series at global scale, such as those pursued by the ESAâs CCI program. It also provides new ideas on the way to merge the different SSM datasets with the aim of producing the CCI (phase 2) long-term series (a coherent "SMOS-AMSR-E" SSM time series for the period 2003 -2014), that will be evaluated further in the framework of on-going ESA projects.L'humiditĂ© du sol (SM) contrĂŽle les bilans dâeau et dâĂ©nergie des surfaces continentales et joue ainsi un rĂŽle clĂ© dans les domaines de la mĂ©tĂ©orologie, l'hydrologie et l'Ă©cologie. La communautĂ© scientifique en tĂ©lĂ©dĂ©tection micro-ondes a fait des efforts considĂ©rables pour Ă©tablir des bases de donnĂ©es globales de lâhumiditĂ© du sol en surface (SSM) dĂ©coulant d'instruments micro-ondes actifs et passifs. Parmi ces instruments, SMOS (Soil Moisture and Ocean Salinity), lancĂ© en 2009, est le premier satellite passif conçu spĂ©cifiquement pour mesurer SSM Ă partir dâobservations en bande L (1.4 GHz) Ă l'Ă©chelle globale. La validation des donnĂ©es SMOS SSM sur diffĂ©rentes rĂ©gions climatiques et pour des conditions environnementales variĂ©es est une Ă©tape indispensable avant quâelles soient utilisĂ©es de maniĂšre opĂ©rationnelle. En effet, une meilleure connaissance de la prĂ©cision des estimations de SSM et des incertitudes associĂ©es permettra non seulement d'amĂ©liorer les produits SMOS SSM, mais aussi d'optimiser les approches de fusion de donnĂ©es utilisĂ©es pour crĂ©er des produits multi-capteurs long terme. De tels produits sont dĂ©veloppĂ©s dans le cadre du programme Climate Change Initiative (CCI) de l'Agence spatiale europĂ©enne (ESA) pour lâensemble des variables climatiques essentielles (ECV), dont SSM. A la suite des chapitres d'introduction I Ă III, les rĂ©sultats de cette thĂšse sont prĂ©sentĂ©s en trois chapitres. Le chapitre IV prĂ©sente une comparaison des produits SSM issus des capteurs passifs SMOS (bande L) et AMSR-E (bande C) en prenant pour rĂ©fĂ©rence les estimations SSM du systĂšme d'assimilation SM-DAS-2 du Centre EuropĂ©en pour les PrĂ©visions MĂ©tĂ©orologiques Ă Moyen Terme (CEPMMT). Cette Ă©valuation est menĂ©e sur la pĂ©riode dâobservation commune Ă SMOS et AMSR-E (2010- 2011), en utilisant des indicateurs classiques (corrĂ©lation, RMSD, Biais). En parallĂšle, le chapitre V prĂ©sente une comparaison des produits SMOS SSM avec les produits SSM issus du capteur actif ASCAT en bande C en utilisant comme rĂ©fĂ©rence les simulations SSM dâun modĂšle des surfaces continentales (MERRA-Land), et en utilisant des indicateurs classiques, des mĂ©thodes statistiques avancĂ©es (triple collocation), et des diagrammes de Hovmöller sur la pĂ©riode 2010-2012. Ces deux Ă©valuations ont montrĂ© que la densitĂ© de la vĂ©gĂ©tation (paramĂ©trĂ©e ici par lâindice foliaire LAI) est un facteur clĂ© pour interprĂ©ter la cohĂ©rence entre le produit SMOS et les produits AMSR-E et ASCAT. Cet effet de la vĂ©gĂ©tation a Ă©tĂ© quantifiĂ© pour la premiĂšre fois Ă lâĂ©chelle globale pour les trois capteurs micro-ondes. Ces deux chapitres ont Ă©galement montrĂ© que les trois capteurs SMOS, AMSR-E et ASCAT ont des performances complĂ©mentaires selon la densitĂ© de vĂ©gĂ©tation et quâil y a ainsi un potentiel intĂ©ressant en terme de fusion des jeux de donnĂ©es micro-ondes passifs et actifs. Dans le chapitre VI, avec lâobjectif gĂ©nĂ©ral dâĂ©tendre vers le passĂ© les sĂ©ries de donnĂ©es SSM de SMOSL3 et de dĂ©velopper un jeu de donnĂ©es SSM homogĂšne sur 2003-2014, nous avons Ă©valuĂ© lâutilisation dâune approche de rĂ©gression linĂ©aire multiple appliquĂ©e aux mesures de tempĂ©ratures de brillance de AMSR-E (2003 - 2011). Les coefficients de rĂ©gression ont Ă©tĂ© calibrĂ©s avec les produits SSM issus de SMOS sur 2010-2011. Le produit SSM rĂ©sultant, qui fusionne les observations SMOS et AMSR-E, a Ă©tĂ© Ă©valuĂ© par comparaison avec un produit SSM AMSR-E et les produits SSM MERRA-Land sur 2007-2009. Ces rĂ©sultats prĂ©liminaires montrent que la mĂ©thode de rĂ©gression linĂ©aire est une approche simple et robuste pour construire un produit SSM rĂ©aliste en termes de variations temporelles et de valeurs absolues. En conclusion, cette thĂšse a montrĂ© que le potentiel de synergie entre les systĂšmes micro-ondes passifs (AMSR-E et SMOS) et actifs (ASCAT) est trĂšs prometteur pour le dĂ©veloppement et l'amĂ©lioration de longues sĂ©ries temporelles SSM Ă l'Ă©chelle mondiale, telles que celles produites dans le cadre du programme CCI de l'ESA
Comparative Evaluation of Microwave L-Band VOD and Optical NDVI for Agriculture Drought Detection over Central Europe
International audienceAgricultural droughts impose many economic and social losses on various communities. Most of the effective tools developed for agricultural drought assessment are based on vegetation indices (VIs). The aim of this study is to compare the response of two commonly used VIs to meteorological droughtsâModerate Resolution Imaging Spectroradiometer (MODIS) normalized difference vegetation index (NDVI) and Soil Moisture and Ocean Salinity (SMOS) vegetation optical depth (VOD). For this purpose, meteorological droughts are calculated by using a standardized precipitation index over more than 24,000 pixels at 0.25° Ă 0.25° spatial resolution located in central Europe. Then, to evaluate the capability of VIs in the detection of agricultural droughts, the average values of VIs anomalies during dry and wet periods obtained from meteorological droughts are statistically compared to each other. Additionally, to assess the response time of VIs to meteorological droughts, a time lag of one to six months is applied to the anomaly time series of VIs during their comparison. Results show that over 35% of the considered pixels NDVI, over 22% of VOD, and over 8% of both VIs anomalies have a significant response to drought events, while the significance level of these differences and the response time of VIs vary with different land use and climate conditions. View Full-Tex
Comparative Evaluation of Microwave L-Band VOD and Optical NDVI for Agriculture Drought Detection over Central Europe
Agricultural droughts impose many economic and social losses on various communities. Most of the effective tools developed for agricultural drought assessment are based on vegetation indices (VIs). The aim of this study is to compare the response of two commonly used VIs to meteorological droughts-Moderate Resolution Imaging Spectroradiometer (MODIS) normalized difference vegetation index (NDVI) and Soil Moisture and Ocean Salinity (SMOS) vegetation optical depth (VOD). For this purpose, meteorological droughts are calculated by using a standardized precipitation index over more than 24,000 pixels at 0.25 degrees x 0.25 degrees spatial resolution located in central Europe. Then, to evaluate the capability of VIs in the detection of agricultural droughts, the average values of VIs anomalies during dry and wet periods obtained from meteorological droughts are statistically compared to each other. Additionally, to assess the response time of VIs to meteorological droughts, a time lag of one to six months is applied to the anomaly time series of VIs during their comparison. Results show that over 35% of the considered pixels NDVI, over 22% of VOD, and over 8% of both VIs anomalies have a significant response to drought events, while the significance level of these differences and the response time of VIs vary with different land use and climate conditions
Beyond Traditional Metrics: Unravelling Hydrological Systems with a Response Time Evaluation Approach
International audienceHydrological, land surface, or climate models are commonly assessed using classical metrics (e.g., Nash-Sutcliffe Efficiency, Root Mean Square Error, etc.) to evaluate their performance in simulating total water storage (S) and streamflow (Q) either separately or jointly. However, these integrative metrics may provide limited insights into the descriptive capabilities of system dynamics, as they heavily rely on the quality of boundary conditions. In contrast to traditional hydrological modelling and approaches that predominantly operate in the time domain, this study introduces a novel approach based on the concept of hydrological âresponse timeâ, physical information linked to system intrinsic properties, which is computed as the ratio S/Q in the frequency domain.This approach explores how different components of the hydrological system respond to variations in input signals at different frequencies, offering reduced sensitivity to boundary conditions. An additional advantage of this approach is its ability to define dominant exchange processes between soil, rivers, and groundwater across various frequency ranges. This methodology contributes to a more robust and physics-based assessment of hydrological system behaviour, fostering a deeper understanding of water dynamics. To demonstrate the effectiveness of this approach, we evaluate Phase 6 of the Coupled Model Intercomparison Project (CMIP6) and the System Global Land Data Assimilation System (GLDAS)-driven Noah models against the Global Runoff Data Centre and the Gravity Recovery and Climate Experiment (GRACE) satellite time series of observed Q and S, respectively, across more than 50 large basins worldwide. The results will be presented and discussed
Comparison of surface soil moisture simulated by the orchidee land surface model with multi-source global satellite products
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Correction: Yao, P. et al. Rebuilding Long Time Series Global Soil Moisture Products Using the Neural Network Adopted the Microwave Vegetation Index. Remote Sens. 2017, 9, 35
After publication of the research paper [1], the authors wish to make the following correction to this paper. In the fourth line from the bottom in abstract, due to a typing error, âRMSE = 0.84 m3/m3â should be replaced with âRMSE = 0.084 m3/m3â.[...
Rebuilding long time series global soil moisture products using the neural network adopting the microwave vegetation index
This study presents a back propagation neural network (BPNN) method to rebuild a global and long-term soil moisture (SM) series, adopting the microwave vegetation index (MVI). The data used in our study include Soil Moisture and Ocean Salinity (SMOS) Level 3 soil moisture (SMOSL3sm) data, the Advanced Microwave Scanning Radiometer-Earth Observing System (AMSR-E), and Advanced Microwave Scanning Radiometer 2 (AMSR2) Level 3 brightness temperature (TB) data and L3 SM products. The BPNNs on each grid were trained over July 2010âJune 2011, and the entire year of 2013, with SMOSL3sm as a training target, and taking the reflectivities (Rs) of the C/X/Ku/Ka/Q bands, and the MVI from AMSR-E/AMSR2 TB data, as input, in which the MVI is used to correct for vegetation effects. The training accuracy of networks was evaluated by comparing soil moisture products produced using BPNNs (NNsm hereafter) with SMOSL3sm during the BPNN training period, in terms of correlation coefficient (CC), bias (Bias), and the root mean square error (RMSE). Good global results were obtained with CC = 0.67, RMSE = 0.055 m3/m3 and Bias = â0.0005 m3/m3, particularly over Australia, Central USA, and Central Asia. With these trained networks over each pixel, a global and long-term soil moisture time series, i.e., 2003â2015, was built using AMSR-E TB from 2003 to 2011 and AMSR2 TB from 2012 to 2015. Then, NNsm products were evaluated against in situ SM observations from all SCAN (Soil Climate Analysis Network) sites (SCANsm). The results show that NNsm has a good agreement with in situ data, and can capture the temporal dynamics of in situ SM, with CC = 0.52, RMSE = 0.84 m3/m3 and Bias = â0.002 m3/m3. We also evaluate the accuracy of NNsm by comparing with AMSR-E/AMSR2 SM products, with results of a regression method. As a conclusion, this study provides a promising BPNN method adopting MVI to rebuild a long-term SM time series, and this could provide useful insights for the future Water Cycle Observation Mission (WCOM)
The role of irrigation expansion on historical climate change during the last 115 years: insights from CMIP6
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