Qualification of a plant disease simulation model: performance of the LATEBLIGHT model across a broad range of environments

The concept of model qualification, i.e., discovering the domain over which a validated model may be properly used, was illustrated with LATEBLIGHT, a mathematical model that simulates the effect of weather, host growth and resistance, and fungicide use on asexual development and growth of Phytophth...

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Bibliographic Details
Published in:Phytopathology 2005-12, Vol.95 (12), p.1412-1422
Main Authors: Andrade-Piedra, J.L, Forbes, G.A, Shtienberg, D, Grunwald, N.J, Chacon, M.G, Taipe, M.V, Hijmans, R.J, Fry, W.E
Format: Article
Language:English
Subjects:
Biological and medical sciences
disease models
disease outbreaks
environmental factors
equations
Fundamental and applied biological sciences. Psychology
fungal diseases of plants
Fungal plant pathogens
leaves
mathematical models
model validation
pathogenicity
Phytopathology. Animal pests. Plant and forest protection
Phytophthora infestans
plant pathogenic fungi
simulation models
Solanum tuberosum
symptoms
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Summary:The concept of model qualification, i.e., discovering the domain over which a validated model may be properly used, was illustrated with LATEBLIGHT, a mathematical model that simulates the effect of weather, host growth and resistance, and fungicide use on asexual development and growth of Phytophthora infestans on potato foliage. Late blight epidemics from Ecuador, Mexico, Israel, and the United States involving 13 potato cultivars (32 epidemics in total) were compared with model predictions using graphical and statistical tests. Fungicides were not applied in any of the epidemics. For the simulations, a host resistance level was assigned to each cultivar based on general categories reported by local investigators. For eight cultivars, the model predictions fit the observed data. For four cultivars, the model predictions overestimated disease, likely due to inaccurate estimates of host resistance. Model predictions were inconsistent for one cultivar and for one location. It was concluded that the domain of applicability of LATEBLIGHT can be extended from the range of conditions in Peru for which it has been previously validated to those observed in this study. A sensitivity analysis showed that, within the range of values observed empirically, LATEBLIGHT is more sensitive to changes in variables related to initial inoculum and to weather than to changes in variables relating to host resistance.
ISSN:0031-949X
1943-7684
DOI:10.1094/PHYTO-95-1412