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Do Agrometeorological Data Improve Optical Satellite-based Estimations of Herbaceous Yield in Sahelian Semi-Arid Ecosystems?

Diouf, Abdoul Aziz; Hiernaux, Pierre; Brandt, Martin et al.

2016 • In Remote Sensing, 8, p. 668

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https://hdl.handle.net/2268/202980

DOI
10.3390/rs8080668

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Keywords :

herbaceous annual yield; FAPAR; start of season; grasslands; GeoWRSI; satellite remote sensing; Cubist; land cover class; Sahel; Senegal

Abstract :

[en] Quantitative estimates of forage availability at the end of the growing season in rangelands are helpful for pastoral livestock managers and for local, national and regional stakeholders in natural resource management. For this reason, remote sensing data such as the Fraction of Absorbed Photosynthetically Active Radiation (FAPAR) have been widely used to assess Sahelian plant productivity for about 40 years. This study combines traditional FAPAR-based assessments with agrometeorological variables computed by the geospatial water balance program, GeoWRSI, using rainfall and potential evapotranspiration satellite gridded data to estimate the annual herbaceous yield in the semi-arid areas of Senegal. It showed that a machine-learning model combining FAPAR seasonal metrics with various agrometeorological data provided better estimations of the in situ annual herbaceous yield (R² = 0.69; RMSE = 483kg•DM/ha) than models based exclusively on FAPAR metrics (R² = 0.63; RMSE = 550kg•DM/ha) or agrometeorological variables (R² = 0.55; RMSE = 585kg•DM/ha). All the models provided reasonable outputs and showed a decrease in the mean annual yield with increasing latitude, together with an increase in relative inter-annual variation. In particular, the additional use of agrometeorological information mitigated the saturation effects that characterize the plant indices of areas with high plant productivity. In addition, the date of the onset of the growing season derived from smoothed FAPAR seasonal dynamics showed no significant relationship (0.05 p-level) with the annual herbaceous yield across the whole studied area. The date of the onset of rainfall however, was significantly related to the herbaceous yield and its inclusion in fodder biomass models could constitute a significant improvement in forecasting risks of a mass herbaceous deficit at an early stage of the year.

Disciplines :

Environmental sciences & ecology

Author, co-author :

Diouf, Abdoul Aziz ; Université de Liège - ULiège > Doct. sc. (sc. & gest. env. - Bologne)

Hiernaux, Pierre

Brandt, Martin

Faye, Gayane

Djaby, Bakary ; Université de Liège - ULiège > DER Sc. et gest. de l'environnement (Arlon Campus Environ.) > Eau, Environnement, Développement

Diop, Mouhamadou Bamba

Ndione, Jacques André

Tychon, Bernard

Language :

English

Title :

Do Agrometeorological Data Improve Optical Satellite-based Estimations of Herbaceous Yield in Sahelian Semi-Arid Ecosystems?

Publication date :

13 August 2016

Journal title :

Remote Sensing

eISSN :

2072-4292

Publisher :

Multidisciplinary Digital Publishing Institute (MDPI), Basel, Switzerland

Volume :

8

Pages :

668

Peer reviewed :

Peer Reviewed verified by ORBi

European Projects :

FP7 - 282621 - AGRICAB - A framework for enhancing EO capacity for Agriculture and Forest Management in Africa as a contribution to GEOSS

Funders :

CE - Commission Européenne

Available on ORBi :

since 30 October 2016

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