A Robust Potato Model : LINTUL-POTATO-DSS
In 1994, LINTUL-POTATO was published, a comprehensive model of potato development and growth. The mechanistic model simulated early crop processes (emergence and leaf expansion) and light interception until extinction, through leaf layers. Photosynthesis and respiration in a previous crop growth model—SUCROS—were substituted by a temperature-dependent light use efficiency. Leaf senescence at initial crop stages was simulated by allowing a longevity per daily leaf class formed, and crop senescence started when all daily dry matter production was allocated to the tubers, leaving none for the foliage. The model performed well in, e.g., ideotyping studies. For other studies such as benchmarking production environments, agro-ecological zoning, climatic hazards, climate change, and yield gap analysis, the need was felt to develop from the original LINTUL-POTATO, a derivative LINTUL-POTATO-DSS with fewer equations—reducing the potential sources of error in calculations—and fewer parameters. This reduces the number of input parameters as well as the amount of data required that for many reasons are not available or not reliable. In LINTUL-POTATO-DSS calculating potential yields, initial crop development depends on a fixed temperature sum for ground cover development from 0% at emergence to 100%. Light use efficiency is temperature dependent. Dry matter distribution to the tubers starts at tuber initiation and linearly increases up to a fixed harvest index which is reached at crop end. Crop end is input of the model: it is assumed that the crop cycle determined by maturity matches the length of the available frost-free and or heat-free cropping season. LINTUL-POTATO-DSS includes novel calculations to explore tuber quality characteristics such as tuber size distribution and dry matter concentration depending on crop environment and management.
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| Format: | Article/Letter to editor biblioteca |
| Language: | English |
| Subjects: | Climate change, Crop growth modeling, Irrigation, Light use efficiency, Nitrogen, Potassium, Tuber dry matter, Tuber size distribution, |
| Online Access: | https://research.wur.nl/en/publications/a-robust-potato-model-lintul-potato-dss |
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dig-wur-nl-wurpubs-4968382025-01-20 Haverkort, A.J. Franke, A.C. Steyn, J.M. Pronk, A.A. Caldiz, D.O. Kooman, P.L. Article/Letter to editor Potato Research 58 (2015) 4 ISSN: 0014-3065 A Robust Potato Model : LINTUL-POTATO-DSS 2015 In 1994, LINTUL-POTATO was published, a comprehensive model of potato development and growth. The mechanistic model simulated early crop processes (emergence and leaf expansion) and light interception until extinction, through leaf layers. Photosynthesis and respiration in a previous crop growth model—SUCROS—were substituted by a temperature-dependent light use efficiency. Leaf senescence at initial crop stages was simulated by allowing a longevity per daily leaf class formed, and crop senescence started when all daily dry matter production was allocated to the tubers, leaving none for the foliage. The model performed well in, e.g., ideotyping studies. For other studies such as benchmarking production environments, agro-ecological zoning, climatic hazards, climate change, and yield gap analysis, the need was felt to develop from the original LINTUL-POTATO, a derivative LINTUL-POTATO-DSS with fewer equations—reducing the potential sources of error in calculations—and fewer parameters. This reduces the number of input parameters as well as the amount of data required that for many reasons are not available or not reliable. In LINTUL-POTATO-DSS calculating potential yields, initial crop development depends on a fixed temperature sum for ground cover development from 0% at emergence to 100%. Light use efficiency is temperature dependent. Dry matter distribution to the tubers starts at tuber initiation and linearly increases up to a fixed harvest index which is reached at crop end. Crop end is input of the model: it is assumed that the crop cycle determined by maturity matches the length of the available frost-free and or heat-free cropping season. LINTUL-POTATO-DSS includes novel calculations to explore tuber quality characteristics such as tuber size distribution and dry matter concentration depending on crop environment and management. en application/pdf https://research.wur.nl/en/publications/a-robust-potato-model-lintul-potato-dss 10.1007/s11540-015-9303-7 https://edepot.wur.nl/372967 Climate change Crop growth modeling Irrigation Light use efficiency Nitrogen Potassium Tuber dry matter Tuber size distribution https://creativecommons.org/licenses/by/4.0/ Wageningen University & Research |
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Climate change Crop growth modeling Irrigation Light use efficiency Nitrogen Potassium Tuber dry matter Tuber size distribution Climate change Crop growth modeling Irrigation Light use efficiency Nitrogen Potassium Tuber dry matter Tuber size distribution |
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Climate change Crop growth modeling Irrigation Light use efficiency Nitrogen Potassium Tuber dry matter Tuber size distribution Climate change Crop growth modeling Irrigation Light use efficiency Nitrogen Potassium Tuber dry matter Tuber size distribution Haverkort, A.J. Franke, A.C. Steyn, J.M. Pronk, A.A. Caldiz, D.O. Kooman, P.L. A Robust Potato Model : LINTUL-POTATO-DSS |
| description |
In 1994, LINTUL-POTATO was published, a comprehensive model of potato development and growth. The mechanistic model simulated early crop processes (emergence and leaf expansion) and light interception until extinction, through leaf layers. Photosynthesis and respiration in a previous crop growth model—SUCROS—were substituted by a temperature-dependent light use efficiency. Leaf senescence at initial crop stages was simulated by allowing a longevity per daily leaf class formed, and crop senescence started when all daily dry matter production was allocated to the tubers, leaving none for the foliage. The model performed well in, e.g., ideotyping studies. For other studies such as benchmarking production environments, agro-ecological zoning, climatic hazards, climate change, and yield gap analysis, the need was felt to develop from the original LINTUL-POTATO, a derivative LINTUL-POTATO-DSS with fewer equations—reducing the potential sources of error in calculations—and fewer parameters. This reduces the number of input parameters as well as the amount of data required that for many reasons are not available or not reliable. In LINTUL-POTATO-DSS calculating potential yields, initial crop development depends on a fixed temperature sum for ground cover development from 0% at emergence to 100%. Light use efficiency is temperature dependent. Dry matter distribution to the tubers starts at tuber initiation and linearly increases up to a fixed harvest index which is reached at crop end. Crop end is input of the model: it is assumed that the crop cycle determined by maturity matches the length of the available frost-free and or heat-free cropping season. LINTUL-POTATO-DSS includes novel calculations to explore tuber quality characteristics such as tuber size distribution and dry matter concentration depending on crop environment and management. |
| format |
Article/Letter to editor |
| topic_facet |
Climate change Crop growth modeling Irrigation Light use efficiency Nitrogen Potassium Tuber dry matter Tuber size distribution |
| author |
Haverkort, A.J. Franke, A.C. Steyn, J.M. Pronk, A.A. Caldiz, D.O. Kooman, P.L. |
| author_facet |
Haverkort, A.J. Franke, A.C. Steyn, J.M. Pronk, A.A. Caldiz, D.O. Kooman, P.L. |
| author_sort |
Haverkort, A.J. |
| title |
A Robust Potato Model : LINTUL-POTATO-DSS |
| title_short |
A Robust Potato Model : LINTUL-POTATO-DSS |
| title_full |
A Robust Potato Model : LINTUL-POTATO-DSS |
| title_fullStr |
A Robust Potato Model : LINTUL-POTATO-DSS |
| title_full_unstemmed |
A Robust Potato Model : LINTUL-POTATO-DSS |
| title_sort |
robust potato model : lintul-potato-dss |
| url |
https://research.wur.nl/en/publications/a-robust-potato-model-lintul-potato-dss |
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