Loading…
Assessing the influence of crop model structure on the performance of data assimilation for sugarcane
•We evaluate the effect of PBM structure on data assimilations.•PBM structure had effect on calibration step performance.•Calibration influenced the performance on OP simulations.•More detailed PBM structure did not inhibit error inconsistency after DA. Process-base crop models (PBM) are important t...
Saved in:
Published in: | Computers and electronics in agriculture 2023-06, Vol.209, p.107848, Article 107848 |
---|---|
Main Authors: | , |
Format: | Article |
Language: | English |
Subjects: | |
Citations: | Items that this one cites Items that cite this one |
Online Access: | Get full text |
Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
Summary: | •We evaluate the effect of PBM structure on data assimilations.•PBM structure had effect on calibration step performance.•Calibration influenced the performance on OP simulations.•More detailed PBM structure did not inhibit error inconsistency after DA.
Process-base crop models (PBM) are important tools to describe how the agricultural system responds to environmental conditions. Sugarcane represents a major world source of sugar and ethanol and its PBMs had different levels of complexity in terms of structure, i.e. how detailed their processes were described. Yet, literature has widely demonstrated that data assimilation techniques (DA) represent a valuable option for reducing model uncertainty, but the inconsistency between PBM and the assimilated variable can significantly affect the performance of DA. Such limitation is strictly connected to model structure, and a hypothesis that arises from literature is that the use of more complex models would reduce model uncertainty after DA. We accessed the performance of using two different PBMs, one more detailed (DSSAT/SAMUCA, DS) and the other more general (WOFOST, WO), by assimilating leaf area index (LAI) retrieved from Landsat 7 ETM + and 8/OLI, using the Ensemble Kalman Filter (EnKF). Both PBMs were calibrated and evaluated with a robust database of 13 experiments and evaluated against a sugarmill database to evaluate the EnKF performance, compared with simulations without DA (Open-loop, OP). Moreover, the processes involved in LAI simulations were analyzed to assess the EnKF performance. The DS had superior performance in the calibration and evaluation step with EF = 0.907, 0.878, 0.458 for stalk dry mass, stalk fresh yield (SFY), and LAI, while WO showed EF = 0.622, 0.610, 0.417 for the same variables, respectively. The calibration step affected the OP plot simulation, with DS having higher accuracy (RMSE = 31.678 Mg ha−1) and precision (R2 = 0.509), compared with WO (RMSE = 39.593 Mg ha−1; R2 = 0.458). However, after DA, both PBM presented error inconsistency with EnKF, despite the decrease in RMSE (-44.73% and −29.58%) and increase in R2 (22.15% and 36.50%) of DS and WO, respectively. The error inconsistency diverged from each PBM: the OP simulation of DS overestimated the Landsat LAI; after DA, simulated LAI decreased resulting in SFY underestimation (Bias = -11.469 Mg ha−1); WO showed OP simulations for LAI closer to Landsat’s LAI values, despite the positive Bias in SFY estimation, and so EnKF slig |
---|---|
ISSN: | 0168-1699 1872-7107 |
DOI: | 10.1016/j.compag.2023.107848 |