Your search keyword '"Robustelli, Monica"' showing total 7 results

1. Harmonization of Fraction of Absorbed Photosynthetically Active Radiation (FAPAR) from Sea-ViewingWide Field-of-View Sensor (SeaWiFS) and Medium Resolution Imaging Spectrometer Instrument (MERIS).

Author

Ceccherini, Guido, Gobron, Nadine, and Robustelli, Monica

Subjects

VEGETATION & climate, AGRICULTURAL climatology, SPECTRUM analysis instruments, SPATIO-temporal variation, CLIMATE change, SEASONAL variations in biogeochemical cycles

Abstract

This paper describes the combination of terrestrial vegetation observations from two sensors, providing a historical dataset used for an in-depth analysis of the corresponding spatio-temporal patterns. The Fraction of Absorbed Photosynthetically Active Radiation (FAPAR) is an important variable suitable for regional to large-scale monitoring of climate impacts on vegetation. In this work, we create an extensive dataset of FAPAR using a 10-day product at ∼1 km resolution from September, 1997, to April, 2012, combining information from two sensors: the NASA/Sea-viewing Wide Field-of-view Sensor (SeaWiFS) and the European Space Agency (ESA)/Medium Resolution Imaging Spectrometer Instrument (MERIS). The proposed methodology reduces the noise, fills the gaps and corrects for the spurious trends in the data, providing a time-consistent coverage of FAPAR. We develop a fast merging method and evaluate its performance over Europe and the Horn of Africa. [ABSTRACT FROM AUTHOR]

Published

2013

2. Diagnostic assessment of European gross primary production.

Author

JUNG, MARTIN, VERSTRAETE, MICHEL, GOBRON, NADINE, REICHSTEIN, MARKUS, PAPALE, DARIO, BONDEAU, ALBERTE, ROBUSTELLI, MONICA, and PINTY, BERNARD

Subjects

ECOLOGICAL research, PRIMARY productivity (Biology), BIOLOGICAL productivity, VEGETATION management, VEGETATION & climate, CARBON cycle, ARTIFICIAL neural networks

Abstract

We present an approach to estimate gross primary production (GPP) using a remotely sensed biophysical vegetation product (fraction of absorbed photosynthetically active radiation, FAPAR) from the European Commission Joint Research Centre (JRC) in conjunction with GPP estimates from eddy covariance measurement towers in Europe. By analysing the relationship between the cumulative growing season FAPAR and annual GPP by vegetation type, we find that the former can be used to accurately predict the latter. The root mean square error of prediction is of the order of 250 gC m−2 yr−1. The cumulative growing season FAPAR integrates over a number of effects relevant for GPP such as the length of the growing season, the vegetation's response to environmental conditions and the amount of light harvested that is available for photosynthesis. We corroborate the proposed GPP estimate (noted FAPAR-based productivity assessment+land cover, FPA+LC) on the continental scale with results from the MOD17+radiation-use efficiency model, an artificial neural network up-scaling approach (ANN) and the Lund–Potsdam–Jena managed Land biosphere model (LPJmL). The closest agreement of the mean spatial GPP pattern among the four models is between FPA+LC and ANN ( R2= 0.74). At least some of the discrepancy between FPA-LC and the other models result from biases of meteorological forcing fields for MOD17+, ANN and LPJmL. Our analysis further implies that meteorological information is to a large degree redundant for GPP estimation when using the JRC-FAPAR. A major advantage of the FPA+LC approach presented in this paper lies in its simplicity and that it requires no additional meteorological input driver data that commonly introduce substantial uncertainty. We find that results from different data-oriented models may be robust enough to evaluate process-oriented models regarding the mean spatial pattern of GPP, while there is too little consensus among the diagnostic models for such purpose regarding inter-annual variability. [ABSTRACT FROM AUTHOR]

Published

2008

3. Can We Use the QA4ECV Black-sky Fraction of Absorbed Photosynthetically Active Radiation (FAPAR) using AVHRR Surface Reflectance to Assess Terrestrial Global Change?

Author

Gobron, Nadine, Marioni, Mirko, Robustelli, Monica, and Vermote, Eric

Subjects

REFLECTANCE, ALGORITHMS, RADIATIVE transfer, RADIATION, QUALITY control, TIME series analysis

Abstract

NOAA platforms provide the longest period of terrestrial observation since the 1980s. The progress in calibration, atmospheric corrections and physically based land retrieval offers the opportunity to reprocess these data for extending terrestrial product time series. Within the Quality Assurance for Essential Climate Variables (QA4ECV) project, the black-sky Joint Research Centre (JRC)-fraction of absorbed photosynthetically active radiation (FAPAR) algorithm was developed for the AVHRR sensors on-board NOAA-07 to -16 using the Land Surface Reflectance Climate Data Record. The retrieval algorithm was based on the radiative transfer theory, and uncertainties were included in the products. We proposed a time and spatial composite for providing both 10-day and monthly products at 0.05° × 0.05°. Quality control and validation were achieved through benchmarking against third-party products, including Sea-Viewing Wide Field-of-View Sensor (SeaWiFS) datasets produced with the same retrieval algorithm. Past ground-based measurements, providing a proxy of FAPAR, showed good agreement of seasonality values over short homogeneous canopies and mixed vegetation. The average difference between SeaWiFS and QA4ECV monthly products over 2002–2005 is about 0.075 with a standard deviation of 0.091. We proposed a monthly linear bias correction that reduced these statistics to 0.02 and 0.001. The complete harmonized long-term time series was then used to address its fitness for the purpose of analysis of global terrestrial change. [ABSTRACT FROM AUTHOR]

Published

2019

4. An automatic procedure to identify key vegetation phenology events using the JRC-FAPAR products

Author

Verstraete, Michel M., Gobron, Nadine, Aussedat, Ophélie, Robustelli, Monica, Pinty, Bernard, Widlowski, Jean-Luc, and Taberner, Malcolm

Subjects

*REMOTE sensing, *AERIAL photogrammetry, *AEROSPACE telemetry, *DETECTORS

Abstract

Abstract: The phenology of vegetation, which describes the seasonal evolution of plants, can be effectively monitored from space. This approach offers important advantages compared to field observations, as quantitative information can be derived for any location worldwide over a number of years, thereby offering a consistent overview of the fate of the observed biomes and their relations with the climate and the environment. This manuscript describes a method to define the start, end, and length of ‘growing seasons’ based on the statistical analysis of time series of the biogeophysical quantity known as the Fraction of Absorbed Photosynthetically Active Radiation derived from an analysis of SeaWiFS data. Results are discussed for various biomes. [Copyright &y& Elsevier]

Published

2008

5. Uncertainty estimates for the FAPAR operational products derived from MERIS — Impact of top-of-atmosphere radiance uncertainties and validation with field data

Author

Gobron, Nadine, Pinty, Bernard, Aussedat, Ophélie, Taberner, Malcolm, Faber, Olga, Mélin, Frédéric, Lavergne, Thomas, Robustelli, Monica, and Snoeij, Paul

Subjects

*SPECTROMETERS, *OPTICAL resolution, *PHOTOSYNTHETICALLY active radiation (PAR), *ALGORITHMS, *TIME series analysis, *UNCERTAINTY, *BRIGHTNESS temperature, *PLANT canopies

Abstract

This paper discusses the accuracy of the operational Medium Resolution Imaging Spectrometer (MERIS) Level 2 land product which corresponds to the Fraction of Absorbed Photosynthetically Active Radiation (FAPAR). The FAPAR value is estimated from daily MERIS spectral measurements acquired at the top-of-atmosphere, using a physically based approach. The products are operationally available at the reduced spatial resolution, i.e. 1.2 km, and can be computed at the full spatial resolution, i.e. at 300 m, from the top-of-atmosphere MERIS data by using the same algorithm. The quality assessment of the MERIS FAPAR products capitalizes on the availability of five years of data acquired globally. The actual validation exercise is performed in two steps including, first, an analysis of the accuracy of the FAPAR algorithm itself with respect to the spectral measurements uncertainties and, second, with a direct comparison of the FAPAR time series against ground-based estimations as well as similar FAPAR products derived from other optical sensor data. The results indicate that the impact of top-of-atmosphere radiance uncertainties on the operational MERIS FAPAR products accuracy is expected to be at about 5–10% and the agreement with the ground-based estimates over different canopy types is achieved within ±0.1. [Copyright &y& Elsevier]

Published

2008

6. Evaluation of the MERIS/ENVISAT FAPAR product

Author

Gobron, Nadine, Pinty, Bernard, Mélin, Frédéric, Taberner, Malcolm, Verstraete, Michel M., Robustelli, Monica, and Widlowski, Jean-Luc

Subjects

*REMOTE sensing, *AEROSPACE telemetry, *ALGORITHMS

Abstract

Abstract: This paper describes the evaluation and performance of the Medium Resolution Imaging Spectrometer (MERIS) Global Vegetation Index (MGVI) algorithm that is implemented in the MERIS ground segment as the primary land surface product. MGVI output values represent the Fraction of Absorbed Photosynthetically Active Radiation (FAPAR) which acts as an indicator of the presence and state of the vegetation canopy. The retrieval algorithm was optimized to be insensitive to the overlying atmosphere, the underlying soil as well as angular effects, using radiative transfer models. This physically based approach for retrieving land biophysical parameters can be extended to a series of sensors; the resulting algorithms are designed to deliver similar geophysical products that are directly comparable and ultimately generate long time series of FAPAR. After presenting the MGVI algorithm, we analyze actual results by inter-comparing the FAPAR values derived from MERIS to similar products derived from the Sea-viewing Wide Field-of-view Sensor (SeaWiFS) that have been generated at the European Commission Joint Research Centre (EC-JRC). The FAPAR products derived from MERIS and SeaWiFS are compared on several dates in 2002 when both instruments simultaneously observed the same geographical regions. The consistency and temporal continuity of the products are then evaluated by comparing the time series of FAPAR values over local sites in Europe during the year 2003 from the two instruments. Finally, multi-annual FAPAR time series obtained by merging MERIS and SeaWiFS products demonstrate the feasibility of monitoring the state of land surfaces with FAPAR products before and after the European drought event in 2003. [Copyright &y& Elsevier]

Published

2007

7. Cross-ECV consistency at global scale: LAI and FAPAR changes.

Author

Mota, Bernardo, Gobron, Nadine, Morgan, Olivier, Cappucci, Fabrizio, Lanconelli, Christian, and Robustelli, Monica

Subjects

*LEAF area index, *LAND cover, *RADIATIVE transfer

Abstract

A framework is proposed for assessing the physical consistency between two terrestrial Essential Climate Variables (ECVs) products retrieved from Earth Observation at global scale. The methodology assessed the level of agreement between the temporal variations of Leaf Area Index (LAI) and Fraction of Absorbed Photosynthetically Active Radiation (FAPAR). The simultaneous changes were classified according to their sign, magnitude and level of confidence, whereby the respective products uncertainties were taken into consideration. A set of proposed agreement metrics were used to identify temporal and spatial biases of non-coherency, non-significance, sensitivity and the overall level of agreement of the temporal changes between two ECVs. We applied the methodology using the Joint Research Center (JRC) Two-stream Inversion Package (TIP) products at 1 km, those provided by the Copernicus Global Land Service (CGLS) based on the SPOT/VGT and Proba-V at 1 km, and the MODIS MCD15A3 at 500 m. In addition, the same analysis was applied with aggregated products at a larger scale over Southern Africa. We found that the CGLS LAI and FAPAR products lacked consistency in their spatial and temporal changes and were severely affected by trends. The MCD15A3 products were characterized by the highest number of non-coherent changes between the two ECVs but temporal inconsistencies were mainly located over the eastern hemisphere. The JRC-TIP products were highly consistent. The results showed the advantages of physically-based retrieval algorithms, in both JRC-TIP and MODIS products, and indicated also that, except for MODIS over forests, aggregated products using an uncertainty-based weighted average led to higher agreement between the ECVs changes. • A new framework to evaluate physical consistency between LAI and FAPAR changes. • Spatial and temporal agreements are assessed considering user confidence level. • Products based on Radiative Transfer Model retrieval show best results. • Results depend on both spatial scale and land cover types. [ABSTRACT FROM AUTHOR]

Published

2021