The ongoing journey of modelling intercropping systems: A conceptual resource sharing intercomparison from model developers and expert users

Adam Muhammad Adam; Myriam Adam; Folkard Asch; Kenneth J. Boote; Vimbayi Grace Petrova Chimonyo; Mathias Christina; Marc Corbeels; Antoine Couëdel; Mathilde De Freitas; Tomas Della Chiesa; Frank Ewert; Gatien N. Falconnier; Kathrin Fuchs; Thomas Gaiser; Ken E. Giller; Gerrit Hoogenboom; Neil Huth; Jibrin Mohammed Jibrin; Eric Justes; Alpha Y. Kamara; Michael Kermah; Nuttapon Khongdee; Eric Koomson; David Kraus; Marcos Lana; Moritz Laub; Betha Lusiana; Carsten Marohn; Patricia Moreno-Cadena; Claas Nendel; Wanwisa Pansak; Willingthon Pavan; Jacques Fils Pierre; Hanna J. Poffenbarger; Ehsan Eyshi Rezaei; Alex C. Ruane; Montserrat Salmerón; Clemens Scheer; Sabine J. Seidel; Pacsu Simwaka; Upendra Singh; Johan Six; Amit Kumar Srivastava; Meine van Noordwijk; Johanna Volk; Jing Yu; Georg Cadisch

doi:10.1016/j.fcr.2026.110491

The ongoing journey of modelling intercropping systems: A conceptual resource sharing intercomparison from model developers and expert users

Adam Muhammad Adam
, Myriam Adam
, Folkard Asch
, Kenneth J. Boote
, Vimbayi Grace Petrova Chimonyo
, Mathias Christina
, Marc Corbeels
, Antoine Couëdel
, Mathilde De Freitas
, Tomas Della Chiesa
, Frank Ewert
, Gatien N. Falconnier
, Kathrin Fuchs
, Thomas Gaiser
, Ken E. Giller
, Gerrit Hoogenboom
, Neil Huth
, Jibrin Mohammed Jibrin
, Eric Justes
, Alpha Y. Kamara

Michael Kermah, Nuttapon Khongdee, Eric Koomson, David Kraus, Marcos Lana, Moritz Laub, Betha Lusiana, Carsten Marohn, Patricia Moreno-Cadena, Claas Nendel, Wanwisa Pansak, Willingthon Pavan, Jacques Fils Pierre, Hanna J. Poffenbarger, Ehsan Eyshi Rezaei, Alex C. Ruane, Montserrat Salmerón, Clemens Scheer, Sabine J. Seidel, Pacsu Simwaka, Upendra Singh, Johan Six, Amit Kumar Srivastava, Meine van Noordwijk, Johanna Volk, Jing Yu, Georg Cadisch

University of Hohenheim
Université Montpellier
UMR AGAP
University of Florida
International Maize and Wheat Improvement Center
CIRAD-Persyst
Centre de coopération internationale en recherche agronomique pour le développement
International Institute of Tropical Agriculture
Universidad de Buenos Aires
Leibniz Centre for Agricultural Landscape Research (ZALF)
University of Bonn
University of Zimbabwe
Institute of Meteorology and Climate Research (IMK-IFU)
Wageningen University & Research
Commonwealth Scientific and Industrial Research Organisation
Bayero University
International Institute of Tropical Agriculture, Ibadan
International Institute of Tropical Agriculture (IITA)
Chiang Mai University
Swedish University of Agricultural Sciences
Swiss Federal Institute of Technology Zurich
The Center for International Forestry Research and World Agroforestry (CIFOR-ICRAF)
Julius Kühn Institute - Federal Research Centre for Cultivated Plants
Research Institute of Organic Agriculture (FiBL)
International Center for Tropical Agriculture (CIAT)
University of Potsdam
Mahidol University
International Fertilizer Development Cente
University of Kentucky
NASA GISS
University of Natural Resources and Life Sciences

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

Abstract

Context: The global shift toward sustainable agriculture has increased interest in using process-based models to design and optimize intercropping systems. However, these models differ fundamentally in how they represent trade-offs (competition for light, water, and nutrients) and synergies (facilitation, complementarity) in resource sharing between species. This conceptual variation creates uncertainty in model selection and application, particularly since most models were originally developed for monoculture and subsequently adapted for intercropping. Objective: In this study, we describe how current crop models represent interspecies resource-sharing mechanisms, analyse their structural differences, and synthesize findings from existing validation studies to understand how their structural differences affect model performance. The models examined include APSIM (APSIM-Canopy, APSIM-Micromet, APSIM-Strip, APSIM-Alternating, APSIM-APSwim, APSIM-SoilArbitrator), DayCent, DSSAT-Mixed, DSSAT-MPI, LandscapeDNDC, LUCIA, MONICA, SIMPLACE Lintul5-Intercrop, STICS-Big-Leaf, STICS-Multilayer, and WaNuLCAS. Methods: Through the Agricultural Model Intercomparison and Improvement Project (AgMIP) platform, we engaged with model developers and expert users to collect detailed information on how crop models represent intercropping systems using structured interviews and questionnaires. We then developed a framework that groups models by their core conceptual approaches to simulating resource sharing. Finally, we synthesize findings from existing quantitative validation studies to connect conceptual intercomparison to predictive performance across different intercrop characteristics and environments. Results and Conclusions: Our analysis identifies six distinct conceptual approaches for simulating light sharing and four for belowground resource (water and nutrient) competition. Intercrop models show greater structural divergence in canopy than in belowground representation. Furthermore, competitive trade-offs (light, water, and nutrients) are widely represented while facilitative and other complex processes like N₂-fixation, plasticity (shoot and root), microclimate effects or hydraulic lift are often simplified or omitted. Our analysis of model validation studies reveals a critical trade-off: structurally complex models often perform well in simulating intercropping when calibration is done on sole crops, whereas simpler models require extensive intercrop-specific calibration to achieve better prediction performance. This distinction is vital for model application in data-scarce environments, as more complex architectures can leverage existing sole-crop data to effectively simulate intercrop systems. The classification of the structural resource capture differences in combination with the evaluated model performance analysis allowed us to devise an evidence-based model selection criteria framework useful also for for non-specialist, while the unique detailed description provided are highly valuable for the model research community. Significance: This study establishes a conceptual framework that provides the necessary foundation for a meaningful quantitative intercomparison of intercrop models, as structural understanding enables the interpretation of numerical differences in model outputs. It also guides hypothesis testing, model choice, priorities in model development and improvements.

Original language	English
Article number	110491
Journal	Field Crops Research
Volume	343
DOIs	https://doi.org/10.1016/j.fcr.2026.110491
Publication status	Published - 1 Jun 2026
Externally published	Yes

Keywords

Agroecological modelling
Agroforestry systems
Diversified systems
Ensemble modelling
Model comparison

Access to Document

10.1016/j.fcr.2026.110491

Cite this

Adam, A. M., Adam, M., Asch, F., Boote, K. J., Chimonyo, V. G. P., Christina, M., Corbeels, M., Couëdel, A., De Freitas, M., Della Chiesa, T., Ewert, F., Falconnier, G. N., Fuchs, K., Gaiser, T., Giller, K. E., Hoogenboom, G., Huth, N., Jibrin, J. M., Justes, E., ... Cadisch, G. (2026). The ongoing journey of modelling intercropping systems: A conceptual resource sharing intercomparison from model developers and expert users. Field Crops Research, 343, Article 110491. https://doi.org/10.1016/j.fcr.2026.110491

@article{d839369874ab4eb389b085d292d278ed,

title = "The ongoing journey of modelling intercropping systems: A conceptual resource sharing intercomparison from model developers and expert users",

abstract = "Context: The global shift toward sustainable agriculture has increased interest in using process-based models to design and optimize intercropping systems. However, these models differ fundamentally in how they represent trade-offs (competition for light, water, and nutrients) and synergies (facilitation, complementarity) in resource sharing between species. This conceptual variation creates uncertainty in model selection and application, particularly since most models were originally developed for monoculture and subsequently adapted for intercropping. Objective: In this study, we describe how current crop models represent interspecies resource-sharing mechanisms, analyse their structural differences, and synthesize findings from existing validation studies to understand how their structural differences affect model performance. The models examined include APSIM (APSIM-Canopy, APSIM-Micromet, APSIM-Strip, APSIM-Alternating, APSIM-APSwim, APSIM-SoilArbitrator), DayCent, DSSAT-Mixed, DSSAT-MPI, LandscapeDNDC, LUCIA, MONICA, SIMPLACE Lintul5-Intercrop, STICS-Big-Leaf, STICS-Multilayer, and WaNuLCAS. Methods: Through the Agricultural Model Intercomparison and Improvement Project (AgMIP) platform, we engaged with model developers and expert users to collect detailed information on how crop models represent intercropping systems using structured interviews and questionnaires. We then developed a framework that groups models by their core conceptual approaches to simulating resource sharing. Finally, we synthesize findings from existing quantitative validation studies to connect conceptual intercomparison to predictive performance across different intercrop characteristics and environments. Results and Conclusions: Our analysis identifies six distinct conceptual approaches for simulating light sharing and four for belowground resource (water and nutrient) competition. Intercrop models show greater structural divergence in canopy than in belowground representation. Furthermore, competitive trade-offs (light, water, and nutrients) are widely represented while facilitative and other complex processes like N₂-fixation, plasticity (shoot and root), microclimate effects or hydraulic lift are often simplified or omitted. Our analysis of model validation studies reveals a critical trade-off: structurally complex models often perform well in simulating intercropping when calibration is done on sole crops, whereas simpler models require extensive intercrop-specific calibration to achieve better prediction performance. This distinction is vital for model application in data-scarce environments, as more complex architectures can leverage existing sole-crop data to effectively simulate intercrop systems. The classification of the structural resource capture differences in combination with the evaluated model performance analysis allowed us to devise an evidence-based model selection criteria framework useful also for for non-specialist, while the unique detailed description provided are highly valuable for the model research community. Significance: This study establishes a conceptual framework that provides the necessary foundation for a meaningful quantitative intercomparison of intercrop models, as structural understanding enables the interpretation of numerical differences in model outputs. It also guides hypothesis testing, model choice, priorities in model development and improvements.",

keywords = "Agroecological modelling, Agroforestry systems, Diversified systems, Ensemble modelling, Model comparison",

author = "Adam, \{Adam Muhammad\} and Myriam Adam and Folkard Asch and Boote, \{Kenneth J.\} and Chimonyo, \{Vimbayi Grace Petrova\} and Mathias Christina and Marc Corbeels and Antoine Cou{\"e}del and \{De Freitas\}, Mathilde and \{Della Chiesa\}, Tomas and Frank Ewert and Falconnier, \{Gatien N.\} and Kathrin Fuchs and Thomas Gaiser and Giller, \{Ken E.\} and Gerrit Hoogenboom and Neil Huth and Jibrin, \{Jibrin Mohammed\} and Eric Justes and Kamara, \{Alpha Y.\} and Michael Kermah and Nuttapon Khongdee and Eric Koomson and David Kraus and Marcos Lana and Moritz Laub and Betha Lusiana and Carsten Marohn and Patricia Moreno-Cadena and Claas Nendel and Wanwisa Pansak and Willingthon Pavan and \{Fils Pierre\}, Jacques and Poffenbarger, \{Hanna J.\} and \{Eyshi Rezaei\}, Ehsan and Ruane, \{Alex C.\} and Montserrat Salmer{\'o}n and Clemens Scheer and Seidel, \{Sabine J.\} and Pacsu Simwaka and Upendra Singh and Johan Six and Srivastava, \{Amit Kumar\} and \{van Noordwijk\}, Meine and Johanna Volk and Jing Yu and Georg Cadisch",

note = "Publisher Copyright: {\textcopyright} 2026 The Authors",

year = "2026",

month = jun,

day = "1",

doi = "10.1016/j.fcr.2026.110491",

language = "English",

volume = "343",

journal = "Field Crops Research",

issn = "0378-4290",

publisher = "Elsevier B.V.",

}

Adam, AM, Adam, M, Asch, F, Boote, KJ, Chimonyo, VGP, Christina, M, Corbeels, M, Couëdel, A, De Freitas, M, Della Chiesa, T, Ewert, F, Falconnier, GN, Fuchs, K, Gaiser, T, Giller, KE, Hoogenboom, G, Huth, N, Jibrin, JM, Justes, E, Kamara, AY, Kermah, M, Khongdee, N, Koomson, E, Kraus, D, Lana, M, Laub, M, Lusiana, B, Marohn, C, Moreno-Cadena, P, Nendel, C, Pansak, W, Pavan, W, Fils Pierre, J, Poffenbarger, HJ, Eyshi Rezaei, E, Ruane, AC, Salmerón, M, Scheer, C, Seidel, SJ, Simwaka, P, Singh, U, Six, J, Srivastava, AK, van Noordwijk, M, Volk, J, Yu, J & Cadisch, G 2026, 'The ongoing journey of modelling intercropping systems: A conceptual resource sharing intercomparison from model developers and expert users', Field Crops Research, vol. 343, 110491. https://doi.org/10.1016/j.fcr.2026.110491

TY - JOUR

T1 - The ongoing journey of modelling intercropping systems

T2 - A conceptual resource sharing intercomparison from model developers and expert users

AU - Adam, Adam Muhammad

AU - Adam, Myriam

AU - Asch, Folkard

AU - Boote, Kenneth J.

AU - Chimonyo, Vimbayi Grace Petrova

AU - Christina, Mathias

AU - Corbeels, Marc

AU - Couëdel, Antoine

AU - De Freitas, Mathilde

AU - Della Chiesa, Tomas

AU - Ewert, Frank

AU - Falconnier, Gatien N.

AU - Fuchs, Kathrin

AU - Gaiser, Thomas

AU - Giller, Ken E.

AU - Hoogenboom, Gerrit

AU - Huth, Neil

AU - Jibrin, Jibrin Mohammed

AU - Justes, Eric

AU - Kamara, Alpha Y.

AU - Kermah, Michael

AU - Khongdee, Nuttapon

AU - Koomson, Eric

AU - Kraus, David

AU - Lana, Marcos

AU - Laub, Moritz

AU - Lusiana, Betha

AU - Marohn, Carsten

AU - Moreno-Cadena, Patricia

AU - Nendel, Claas

AU - Pansak, Wanwisa

AU - Pavan, Willingthon

AU - Fils Pierre, Jacques

AU - Poffenbarger, Hanna J.

AU - Eyshi Rezaei, Ehsan

AU - Ruane, Alex C.

AU - Salmerón, Montserrat

AU - Scheer, Clemens

AU - Seidel, Sabine J.

AU - Simwaka, Pacsu

AU - Singh, Upendra

AU - Six, Johan

AU - Srivastava, Amit Kumar

AU - van Noordwijk, Meine

AU - Volk, Johanna

AU - Yu, Jing

AU - Cadisch, Georg

PY - 2026/6/1

Y1 - 2026/6/1

N2 - Context: The global shift toward sustainable agriculture has increased interest in using process-based models to design and optimize intercropping systems. However, these models differ fundamentally in how they represent trade-offs (competition for light, water, and nutrients) and synergies (facilitation, complementarity) in resource sharing between species. This conceptual variation creates uncertainty in model selection and application, particularly since most models were originally developed for monoculture and subsequently adapted for intercropping. Objective: In this study, we describe how current crop models represent interspecies resource-sharing mechanisms, analyse their structural differences, and synthesize findings from existing validation studies to understand how their structural differences affect model performance. The models examined include APSIM (APSIM-Canopy, APSIM-Micromet, APSIM-Strip, APSIM-Alternating, APSIM-APSwim, APSIM-SoilArbitrator), DayCent, DSSAT-Mixed, DSSAT-MPI, LandscapeDNDC, LUCIA, MONICA, SIMPLACE Lintul5-Intercrop, STICS-Big-Leaf, STICS-Multilayer, and WaNuLCAS. Methods: Through the Agricultural Model Intercomparison and Improvement Project (AgMIP) platform, we engaged with model developers and expert users to collect detailed information on how crop models represent intercropping systems using structured interviews and questionnaires. We then developed a framework that groups models by their core conceptual approaches to simulating resource sharing. Finally, we synthesize findings from existing quantitative validation studies to connect conceptual intercomparison to predictive performance across different intercrop characteristics and environments. Results and Conclusions: Our analysis identifies six distinct conceptual approaches for simulating light sharing and four for belowground resource (water and nutrient) competition. Intercrop models show greater structural divergence in canopy than in belowground representation. Furthermore, competitive trade-offs (light, water, and nutrients) are widely represented while facilitative and other complex processes like N₂-fixation, plasticity (shoot and root), microclimate effects or hydraulic lift are often simplified or omitted. Our analysis of model validation studies reveals a critical trade-off: structurally complex models often perform well in simulating intercropping when calibration is done on sole crops, whereas simpler models require extensive intercrop-specific calibration to achieve better prediction performance. This distinction is vital for model application in data-scarce environments, as more complex architectures can leverage existing sole-crop data to effectively simulate intercrop systems. The classification of the structural resource capture differences in combination with the evaluated model performance analysis allowed us to devise an evidence-based model selection criteria framework useful also for for non-specialist, while the unique detailed description provided are highly valuable for the model research community. Significance: This study establishes a conceptual framework that provides the necessary foundation for a meaningful quantitative intercomparison of intercrop models, as structural understanding enables the interpretation of numerical differences in model outputs. It also guides hypothesis testing, model choice, priorities in model development and improvements.

AB - Context: The global shift toward sustainable agriculture has increased interest in using process-based models to design and optimize intercropping systems. However, these models differ fundamentally in how they represent trade-offs (competition for light, water, and nutrients) and synergies (facilitation, complementarity) in resource sharing between species. This conceptual variation creates uncertainty in model selection and application, particularly since most models were originally developed for monoculture and subsequently adapted for intercropping. Objective: In this study, we describe how current crop models represent interspecies resource-sharing mechanisms, analyse their structural differences, and synthesize findings from existing validation studies to understand how their structural differences affect model performance. The models examined include APSIM (APSIM-Canopy, APSIM-Micromet, APSIM-Strip, APSIM-Alternating, APSIM-APSwim, APSIM-SoilArbitrator), DayCent, DSSAT-Mixed, DSSAT-MPI, LandscapeDNDC, LUCIA, MONICA, SIMPLACE Lintul5-Intercrop, STICS-Big-Leaf, STICS-Multilayer, and WaNuLCAS. Methods: Through the Agricultural Model Intercomparison and Improvement Project (AgMIP) platform, we engaged with model developers and expert users to collect detailed information on how crop models represent intercropping systems using structured interviews and questionnaires. We then developed a framework that groups models by their core conceptual approaches to simulating resource sharing. Finally, we synthesize findings from existing quantitative validation studies to connect conceptual intercomparison to predictive performance across different intercrop characteristics and environments. Results and Conclusions: Our analysis identifies six distinct conceptual approaches for simulating light sharing and four for belowground resource (water and nutrient) competition. Intercrop models show greater structural divergence in canopy than in belowground representation. Furthermore, competitive trade-offs (light, water, and nutrients) are widely represented while facilitative and other complex processes like N₂-fixation, plasticity (shoot and root), microclimate effects or hydraulic lift are often simplified or omitted. Our analysis of model validation studies reveals a critical trade-off: structurally complex models often perform well in simulating intercropping when calibration is done on sole crops, whereas simpler models require extensive intercrop-specific calibration to achieve better prediction performance. This distinction is vital for model application in data-scarce environments, as more complex architectures can leverage existing sole-crop data to effectively simulate intercrop systems. The classification of the structural resource capture differences in combination with the evaluated model performance analysis allowed us to devise an evidence-based model selection criteria framework useful also for for non-specialist, while the unique detailed description provided are highly valuable for the model research community. Significance: This study establishes a conceptual framework that provides the necessary foundation for a meaningful quantitative intercomparison of intercrop models, as structural understanding enables the interpretation of numerical differences in model outputs. It also guides hypothesis testing, model choice, priorities in model development and improvements.

KW - Agroecological modelling

KW - Agroforestry systems

KW - Diversified systems

KW - Ensemble modelling

KW - Model comparison

UR - https://www.scopus.com/pages/publications/105037123595

U2 - 10.1016/j.fcr.2026.110491

DO - 10.1016/j.fcr.2026.110491

M3 - Article

AN - SCOPUS:105037123595

SN - 0378-4290

VL - 343

JO - Field Crops Research

JF - Field Crops Research

M1 - 110491

ER -

The ongoing journey of modelling intercropping systems: A conceptual resource sharing intercomparison from model developers and expert users

Abstract

Keywords

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