Proposal and extensive test of a calibration protocol for crop phenology models

Daniel Wallach; Taru Palosuo; Peter Thorburn; Henrike Mielenz; Samuel Buis; Zvi Hochman; Emmanuelle Gourdain; Fety Andrianasolo; Benjamin Dumont; Roberto Ferrise; Thomas Gaiser; Cecile Garcia; Sebastian Gayler; Matthew Harrison; Santosh Hiremath; Heidi Horan; Gerrit Hoogenboom; Per Erik Jansson; Qi Jing; Eric Justes; Kurt Christian Kersebaum; Marie Launay; Elisabet Lewan; Ke Liu; Fasil Mequanint; Marco Moriondo; Claas Nendel; Gloria Padovan; Budong Qian; Niels Schütze; Diana Maria Seserman; Vakhtang Shelia; Amir Souissi; Xenia Specka; Amit Kumar Srivastava; Giacomo Trombi; Tobias K.D. Weber; Lutz Weihermüller; Thomas Wöhling; Sabine J. Seidel

doi:10.1007/s13593-023-00900-0

Proposal and extensive test of a calibration protocol for crop phenology models

Daniel Wallach, Taru Palosuo, Peter Thorburn, Henrike Mielenz, Samuel Buis, Zvi Hochman, Emmanuelle Gourdain, Fety Andrianasolo, Benjamin Dumont, Roberto Ferrise, Thomas Gaiser, Cecile Garcia, Sebastian Gayler, Matthew Harrison, Santosh Hiremath, Heidi Horan, Gerrit Hoogenboom, Per Erik Jansson, Qi Jing, Eric JustesKurt Christian Kersebaum, Marie Launay, Elisabet Lewan, Ke Liu, Fasil Mequanint, Marco Moriondo, Claas Nendel, Gloria Padovan, Budong Qian, Niels Schütze, Diana Maria Seserman, Vakhtang Shelia, Amir Souissi, Xenia Specka, Amit Kumar Srivastava, Giacomo Trombi, Tobias K.D. Weber, Lutz Weihermüller, Thomas Wöhling, Sabine J. Seidel^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

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Abstract

A major effect of environment on crops is through crop phenology, and therefore, the capacity to predict phenology for new environments is important. Mechanistic crop models are a major tool for such predictions, but calibration of crop phenology models is difficult and there is no consensus on the best approach. We propose an original, detailed approach for calibration of such models, which we refer to as a calibration protocol. The protocol covers all the steps in the calibration workflow, namely choice of default parameter values, choice of objective function, choice of parameters to estimate from the data, calculation of optimal parameter values, and diagnostics. The major innovation is in the choice of which parameters to estimate from the data, which combines expert knowledge and data-based model selection. First, almost additive parameters are identified and estimated. This should make bias (average difference between observed and simulated values) nearly zero. These are “obligatory” parameters, that will definitely be estimated. Then candidate parameters are identified, which are parameters likely to explain the remaining discrepancies between simulated and observed values. A candidate is only added to the list of parameters to estimate if it leads to a reduction in BIC (Bayesian Information Criterion), which is a model selection criterion. A second original aspect of the protocol is the specification of documentation for each stage of the protocol. The protocol was applied by 19 modeling teams to three data sets for wheat phenology. All teams first calibrated their model using their “usual” calibration approach, so it was possible to compare usual and protocol calibration. Evaluation of prediction error was based on data from sites and years not represented in the training data. Compared to usual calibration, calibration following the new protocol reduced the variability between modeling teams by 22% and reduced prediction error by 11%.

Original language	English
Article number	46
Journal	Agronomy for Sustainable Development
Volume	43
Issue number	4
DOIs	https://doi.org/10.1007/s13593-023-00900-0
Publication status	Published - Aug 2023
MoE publication type	A1 Journal article-refereed

Keywords

Crop model
Model ensemble
Prediction error
Protocol
Variability

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10.1007/s13593-023-00900-0

Proposal and extensive test of a calibration protocol for crop phenology modelsFinal published version, 0.99 MBLicence: CC BY

Cite this

Wallach, D., Palosuo, T., Thorburn, P., Mielenz, H., Buis, S., Hochman, Z., Gourdain, E., Andrianasolo, F., Dumont, B., Ferrise, R., Gaiser, T., Garcia, C., Gayler, S., Harrison, M., Hiremath, S., Horan, H., Hoogenboom, G., Jansson, P. E., Jing, Q., ... Seidel, S. J. (2023). Proposal and extensive test of a calibration protocol for crop phenology models. Agronomy for Sustainable Development, 43(4), Article 46. https://doi.org/10.1007/s13593-023-00900-0

@article{618b4d3673ac47819f27166f8d46395c,

title = "Proposal and extensive test of a calibration protocol for crop phenology models",

abstract = "A major effect of environment on crops is through crop phenology, and therefore, the capacity to predict phenology for new environments is important. Mechanistic crop models are a major tool for such predictions, but calibration of crop phenology models is difficult and there is no consensus on the best approach. We propose an original, detailed approach for calibration of such models, which we refer to as a calibration protocol. The protocol covers all the steps in the calibration workflow, namely choice of default parameter values, choice of objective function, choice of parameters to estimate from the data, calculation of optimal parameter values, and diagnostics. The major innovation is in the choice of which parameters to estimate from the data, which combines expert knowledge and data-based model selection. First, almost additive parameters are identified and estimated. This should make bias (average difference between observed and simulated values) nearly zero. These are “obligatory” parameters, that will definitely be estimated. Then candidate parameters are identified, which are parameters likely to explain the remaining discrepancies between simulated and observed values. A candidate is only added to the list of parameters to estimate if it leads to a reduction in BIC (Bayesian Information Criterion), which is a model selection criterion. A second original aspect of the protocol is the specification of documentation for each stage of the protocol. The protocol was applied by 19 modeling teams to three data sets for wheat phenology. All teams first calibrated their model using their “usual” calibration approach, so it was possible to compare usual and protocol calibration. Evaluation of prediction error was based on data from sites and years not represented in the training data. Compared to usual calibration, calibration following the new protocol reduced the variability between modeling teams by 22% and reduced prediction error by 11%.",

keywords = "Crop model, Model ensemble, Prediction error, Protocol, Variability",

author = "Daniel Wallach and Taru Palosuo and Peter Thorburn and Henrike Mielenz and Samuel Buis and Zvi Hochman and Emmanuelle Gourdain and Fety Andrianasolo and Benjamin Dumont and Roberto Ferrise and Thomas Gaiser and Cecile Garcia and Sebastian Gayler and Matthew Harrison and Santosh Hiremath and Heidi Horan and Gerrit Hoogenboom and Jansson, {Per Erik} and Qi Jing and Eric Justes and Kersebaum, {Kurt Christian} and Marie Launay and Elisabet Lewan and Ke Liu and Fasil Mequanint and Marco Moriondo and Claas Nendel and Gloria Padovan and Budong Qian and Niels Sch{\"u}tze and Seserman, {Diana Maria} and Vakhtang Shelia and Amir Souissi and Xenia Specka and Srivastava, {Amit Kumar} and Giacomo Trombi and Weber, {Tobias K.D.} and Lutz Weiherm{\"u}ller and Thomas W{\"o}hling and Seidel, {Sabine J.}",

note = "Funding Information: Open Access funding enabled and organized by Projekt DEAL. This study was implemented as a co-operative project under the umbrella of the Agricultural Model Intercomparison and Improvement Project (AgMIP). This work was supported by the Academy of Finland through projects AI-CropPro (316172 and 315896) and DivCSA (316215) and Natural Resources Institute Finland (Luke) through a strategic project EFFI, the German Federal Ministry of Education and Research (BMBF) in the framework of the funding measure “Soil as a Sustainable Resource for the Bioeconomy - BonaRes”, project “BonaRes (Module B, Phase 3): BonaRes Centre for Soil Research, subproject B” (grant 031B1064B), the BonaRes project “I4S” (031B0513I) of the Federal Ministry of Education and Research (BMBF), Germany, the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under Germany{\textquoteright}s Excellence Strategy - EXC 2070 -390732324 EXC (PhenoRob), the Ministry of Education, Youth and Sports of Czech Republic through SustES - Adaption strategies for sustainable ecosystem services and food security under adverse environmental conditions (project no. CZ.02.1.01/0.0/0.0/16_019/000797), the Agriculture and Agri-Food Canada{\textquoteright}s Project J-002303 “Sustainable crop production in Canada under climate change” under the Interdepartmental Research Initiative in Agriculture, the JPI FACCE MACSUR2 project, funded by the Italian Ministry for Agricultural, Food, and Forestry Policies (D.M. 24064/7303/15 of 6/Nov/2015), and the INRAE CLIMAE meta-program and AgroEcoSystem department. The order in which the donors are listed is arbitrary. Publisher Copyright: {\textcopyright} 2023, The Author(s).",

year = "2023",

month = aug,

doi = "10.1007/s13593-023-00900-0",

language = "English",

volume = "43",

journal = "Agronomy for Sustainable Development",

issn = "1774-0746",

publisher = "Springer",

number = "4",

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Wallach, D, Palosuo, T, Thorburn, P, Mielenz, H, Buis, S, Hochman, Z, Gourdain, E, Andrianasolo, F, Dumont, B, Ferrise, R, Gaiser, T, Garcia, C, Gayler, S, Harrison, M, Hiremath, S, Horan, H, Hoogenboom, G, Jansson, PE, Jing, Q, Justes, E, Kersebaum, KC, Launay, M, Lewan, E, Liu, K, Mequanint, F, Moriondo, M, Nendel, C, Padovan, G, Qian, B, Schütze, N, Seserman, DM, Shelia, V, Souissi, A, Specka, X, Srivastava, AK, Trombi, G, Weber, TKD, Weihermüller, L, Wöhling, T & Seidel, SJ 2023, 'Proposal and extensive test of a calibration protocol for crop phenology models', Agronomy for Sustainable Development, vol. 43, no. 4, 46. https://doi.org/10.1007/s13593-023-00900-0

TY - JOUR

T1 - Proposal and extensive test of a calibration protocol for crop phenology models

AU - Wallach, Daniel

AU - Palosuo, Taru

AU - Thorburn, Peter

AU - Mielenz, Henrike

AU - Buis, Samuel

AU - Hochman, Zvi

AU - Gourdain, Emmanuelle

AU - Andrianasolo, Fety

AU - Dumont, Benjamin

AU - Ferrise, Roberto

AU - Gaiser, Thomas

AU - Garcia, Cecile

AU - Gayler, Sebastian

AU - Harrison, Matthew

AU - Hiremath, Santosh

AU - Horan, Heidi

AU - Hoogenboom, Gerrit

AU - Jansson, Per Erik

AU - Jing, Qi

AU - Justes, Eric

AU - Kersebaum, Kurt Christian

AU - Launay, Marie

AU - Lewan, Elisabet

AU - Liu, Ke

AU - Mequanint, Fasil

AU - Moriondo, Marco

AU - Nendel, Claas

AU - Padovan, Gloria

AU - Qian, Budong

AU - Schütze, Niels

AU - Seserman, Diana Maria

AU - Shelia, Vakhtang

AU - Souissi, Amir

AU - Specka, Xenia

AU - Srivastava, Amit Kumar

AU - Trombi, Giacomo

AU - Weber, Tobias K.D.

AU - Weihermüller, Lutz

AU - Wöhling, Thomas

AU - Seidel, Sabine J.

N1 - Funding Information: Open Access funding enabled and organized by Projekt DEAL. This study was implemented as a co-operative project under the umbrella of the Agricultural Model Intercomparison and Improvement Project (AgMIP). This work was supported by the Academy of Finland through projects AI-CropPro (316172 and 315896) and DivCSA (316215) and Natural Resources Institute Finland (Luke) through a strategic project EFFI, the German Federal Ministry of Education and Research (BMBF) in the framework of the funding measure “Soil as a Sustainable Resource for the Bioeconomy - BonaRes”, project “BonaRes (Module B, Phase 3): BonaRes Centre for Soil Research, subproject B” (grant 031B1064B), the BonaRes project “I4S” (031B0513I) of the Federal Ministry of Education and Research (BMBF), Germany, the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under Germany’s Excellence Strategy - EXC 2070 -390732324 EXC (PhenoRob), the Ministry of Education, Youth and Sports of Czech Republic through SustES - Adaption strategies for sustainable ecosystem services and food security under adverse environmental conditions (project no. CZ.02.1.01/0.0/0.0/16_019/000797), the Agriculture and Agri-Food Canada’s Project J-002303 “Sustainable crop production in Canada under climate change” under the Interdepartmental Research Initiative in Agriculture, the JPI FACCE MACSUR2 project, funded by the Italian Ministry for Agricultural, Food, and Forestry Policies (D.M. 24064/7303/15 of 6/Nov/2015), and the INRAE CLIMAE meta-program and AgroEcoSystem department. The order in which the donors are listed is arbitrary. Publisher Copyright: © 2023, The Author(s).

PY - 2023/8

Y1 - 2023/8

N2 - A major effect of environment on crops is through crop phenology, and therefore, the capacity to predict phenology for new environments is important. Mechanistic crop models are a major tool for such predictions, but calibration of crop phenology models is difficult and there is no consensus on the best approach. We propose an original, detailed approach for calibration of such models, which we refer to as a calibration protocol. The protocol covers all the steps in the calibration workflow, namely choice of default parameter values, choice of objective function, choice of parameters to estimate from the data, calculation of optimal parameter values, and diagnostics. The major innovation is in the choice of which parameters to estimate from the data, which combines expert knowledge and data-based model selection. First, almost additive parameters are identified and estimated. This should make bias (average difference between observed and simulated values) nearly zero. These are “obligatory” parameters, that will definitely be estimated. Then candidate parameters are identified, which are parameters likely to explain the remaining discrepancies between simulated and observed values. A candidate is only added to the list of parameters to estimate if it leads to a reduction in BIC (Bayesian Information Criterion), which is a model selection criterion. A second original aspect of the protocol is the specification of documentation for each stage of the protocol. The protocol was applied by 19 modeling teams to three data sets for wheat phenology. All teams first calibrated their model using their “usual” calibration approach, so it was possible to compare usual and protocol calibration. Evaluation of prediction error was based on data from sites and years not represented in the training data. Compared to usual calibration, calibration following the new protocol reduced the variability between modeling teams by 22% and reduced prediction error by 11%.

AB - A major effect of environment on crops is through crop phenology, and therefore, the capacity to predict phenology for new environments is important. Mechanistic crop models are a major tool for such predictions, but calibration of crop phenology models is difficult and there is no consensus on the best approach. We propose an original, detailed approach for calibration of such models, which we refer to as a calibration protocol. The protocol covers all the steps in the calibration workflow, namely choice of default parameter values, choice of objective function, choice of parameters to estimate from the data, calculation of optimal parameter values, and diagnostics. The major innovation is in the choice of which parameters to estimate from the data, which combines expert knowledge and data-based model selection. First, almost additive parameters are identified and estimated. This should make bias (average difference between observed and simulated values) nearly zero. These are “obligatory” parameters, that will definitely be estimated. Then candidate parameters are identified, which are parameters likely to explain the remaining discrepancies between simulated and observed values. A candidate is only added to the list of parameters to estimate if it leads to a reduction in BIC (Bayesian Information Criterion), which is a model selection criterion. A second original aspect of the protocol is the specification of documentation for each stage of the protocol. The protocol was applied by 19 modeling teams to three data sets for wheat phenology. All teams first calibrated their model using their “usual” calibration approach, so it was possible to compare usual and protocol calibration. Evaluation of prediction error was based on data from sites and years not represented in the training data. Compared to usual calibration, calibration following the new protocol reduced the variability between modeling teams by 22% and reduced prediction error by 11%.

KW - Crop model

KW - Model ensemble

KW - Prediction error

KW - Protocol

KW - Variability

UR - http://www.scopus.com/inward/record.url?scp=85165277995&partnerID=8YFLogxK

U2 - 10.1007/s13593-023-00900-0

DO - 10.1007/s13593-023-00900-0

M3 - Article

AN - SCOPUS:85165277995

SN - 1774-0746

VL - 43

JO - Agronomy for Sustainable Development

JF - Agronomy for Sustainable Development

IS - 4

M1 - 46

ER -

Proposal and extensive test of a calibration protocol for crop phenology models

Abstract

Keywords

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-: Intelligent Crop Production: Data-integrative, Multi-task Learning Meets Crop Simulator

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Proposal and extensive test of a calibration protocol for crop phenology models

Abstract

Keywords

Access to Document

Other files and links

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Projects

-: Intelligent Crop Production: Data-integrative, Multi-task Learning Meets Crop Simulator

Cite this