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Batch-processing of AquaCrop plug-in for rainfed maize using satellite derived Fractional Vegetation Cover data

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  • Mohamed Sallah, Abdoul-Hamid
  • Tychon, Bernard
  • Piccard, Isabelle
  • Gobin, Anne
  • Van Hoolst, Roel
  • Djaby, Bakary
  • Wellens, Joost

Abstract

Coupling crop growth models and remote sensing data has shown great potential to improve crop yield and biomass forecasting. However, few such applications are used at field level. In this study, the plug-in version of AquaCrop, a water driven model initially designed for conditions in which water is the limiting factor in crop production, was adapted to assess maize in Belgium. Field campaigns were organised in 2015, 2016 and 2017, during which ground measurements were collected. At field level and under rainfed conditions, above ground total dry biomass and field management information (crop density, planting dates, biomass measurements etc.) was collected. Green fractional vegetation cover (fCover) data were retrieved from high spatial and temporal satellite images (DMC-2/ DEIMOS-1 and Sentinel-2). Maximum canopy cover and emergence date were derived from the time series and assimilated into AquaCrop. The model was calibrated with the 2015–2016 dataset and validated with 2017 data. The root mean square error (RMSE) for the biomass assessment was 0.7 ton/ha and the R² reached 0.85. The R² between the canopy cover simulated by the model and the remotely sensed fCover ranged from 0.76–0.98 in most of the cases. To simultaneously run and evaluate the ensemble of field-level simulations, a semi-automated R-environment was developed. This robust and automated approach offers vast potential for large-scale field-level yield assessments for temperate as well as tropical conditions.

Suggested Citation

  • Mohamed Sallah, Abdoul-Hamid & Tychon, Bernard & Piccard, Isabelle & Gobin, Anne & Van Hoolst, Roel & Djaby, Bakary & Wellens, Joost, 2019. "Batch-processing of AquaCrop plug-in for rainfed maize using satellite derived Fractional Vegetation Cover data," Agricultural Water Management, Elsevier, vol. 217(C), pages 346-355.
    • Handle: RePEc:eee:agiwat:v:217:y:2019:i:c:p:346-355
    DOI: 10.1016/j.agwat.2019.03.016
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    1. Abedinpour, M. & Sarangi, A. & Rajput, T.B.S. & Singh, Man & Pathak, H. & Ahmad, T., 2012. "Performance evaluation of AquaCrop model for maize crop in a semi-arid environment," Agricultural Water Management, Elsevier, vol. 110(C), pages 55-66.
    2. Wellens, Joost & Raes, Dirk & Traore, Farid & Denis, Antoine & Djaby, Bakary & Tychon, Bernard, 2013. "Performance assessment of the FAO AquaCrop model for irrigated cabbage on farmer plots in a semi-arid environment," Agricultural Water Management, Elsevier, vol. 127(C), pages 40-47.
    3. Trombetta, Andrea & Iacobellis, Vito & Tarantino, Eufemia & Gentile, Francesco, 2016. "Calibration of the AquaCrop model for winter wheat using MODIS LAI images," Agricultural Water Management, Elsevier, vol. 164(P2), pages 304-316.
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    1. Alvar-Beltrán, Jorge & Saturnin, Coulibaly & Grégoire, Baki & Camacho, Jose Luís & Dao, Abdalla & Migraine, Jean Baptiste & Marta, Anna Dalla, 2023. "Using AquaCrop as a decision-support tool for improved irrigation management in the Sahel region," Agricultural Water Management, Elsevier, vol. 287(C).
    2. Liu, Xiao & Yang, Dawen, 2021. "Irrigation schedule analysis and optimization under the different combination of P and ET0 using a spatially distributed crop model," Agricultural Water Management, Elsevier, vol. 256(C).
    3. Tsakmakis, I.D. & Gikas, G.D. & Sylaios, G.K., 2021. "Integration of Sentinel-derived NDVI to reduce uncertainties in the operational field monitoring of maize," Agricultural Water Management, Elsevier, vol. 255(C).

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