Claverie M., Demarez V., Duchemin Benoît, Hagolle O., Ducrot D., Marais-Sicre C., Dejoux J. F., Huc M., Keravec P., Beziat P., Fieuzal R., Ceschia E., Dedieu G. (2012). Maize and sunflower biomass estimation in southwest France using high spatial and temporal resolution remote sensing data. Remote Sensing of Environment, 124, p. 844-857. ISSN 0034-4257.
Titre du document
Maize and sunflower biomass estimation in southwest France using high spatial and temporal resolution remote sensing data
Année de publication
2012
Auteurs
Claverie M., Demarez V., Duchemin Benoît, Hagolle O., Ducrot D., Marais-Sicre C., Dejoux J. F., Huc M., Keravec P., Beziat P., Fieuzal R., Ceschia E., Dedieu G.
Source
Remote Sensing of Environment, 2012,
124, p. 844-857 ISSN 0034-4257
The recent availability of high spatial and temporal resolution (HSTR) remote sensing data (Formosat-2, and future missions of Ven mu s and Sentinel-2) offers new opportunities for crop monitoring. In this context, we investigated the perspective offered by coupling a simple algorithm for yield estimate (SAFY) with the Formosat-2 data to estimate crop production over large areas. With a limited number of input parameters, the SAFY model enables the simulation of time series of green area index (GAI) and dry aboveground biomass (DAM). From 2006 to 2009, 95 Formosat-2 images (8 m, 1 day revisit) were acquired for a 24 x 24 km(2) area southwest of Toulouse, France. This study focused on two summer crops: irrigated maize (Zea mays) and sunflower (Helianthus annuus). Green area index (GAI) time series were deduced from Formosat-2 NDVI time series and were used to calibrate six major parameters of the SAFY model. Four of those parameters (partition-to-leaf and senescence function parameters) were calibrated per crop type based on the very dense 2006 Formosat-2 data set The retrieved values of these parameters were consistent with the in situ observations and a literature review. Two of the major parameters of the SAFY model (emergence day and effective light-use efficiency) were calibrated per field relative to crop management practices. The estimated effective light-use efficiency values highlighted the distinction between the C4 (maize) and 0 (sunflower) plants, and were linked to the reduction of the photosynthesis rate due to water stress. The model was able to reproduce a large set of GAI temporal shapes, which were related to various phenological behaviours and to crop type. The biomass was well estimated (relative error of 28%), especially considering that biomass measurements were not used for the calibration. The grain yields were also simulated using harvest index coefficients and were compared with grain yield statistics from the French Agricultural Statistics for the department of Haute-Garonne. The inter-annual variation in the simulated grain yields of sunflower was consistent with the reported variation. For maize, significant discrepancies were observed with the reported statistics.
Plan de classement
Sciences fondamentales / Techniques d'analyse et de recherche [020]
;
Télédétection [126]
Description Géographique
FRANCE
Localisation
Fonds IRD [F B010058179]
Identifiant IRD
fdi:010058179
