Development and validation of a phenological model for the univoltine European corn borer

Biological control of a univoltine race of European corn borer, Ostrinia nubilalis Hübner (Lepidoptera: Crambidae), by Trichogramma in Switzerland is currently timed according to repeated, semi‐field observations of the post‐diapause development of the pest at one site. We developed a phenology mode...

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Vydáno v:Journal of applied entomology (1986) Ročník 141; číslo 6; s. 421 - 430
Hlavní autoři: Schaub, L., Breitenmoser, S., Derron, J., Graf, B.
Médium: Journal Article
Jazyk:angličtina
Vydáno: Berlin Wiley Subscription Services, Inc 01.07.2017
Témata:
Biological control
Calibration
Computer simulation
Corn
Delay
Diapause
Drying
Emergence
flight
heat sums
Humidity
labor
landscapes
larvae
Light traps
Mathematical models
Ostrinia nubilalis
pests
Phenology
prediction
pupal development
Pupation
Simulation
simulation models
spring
Spring (season)
Switzerland
temperature
Temperature effects
Time measurement
Trichogramma
univoltine
univoltine habit
Zea mays
Switzerland
ISSN:0931-2048, 1439-0418
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Shrnutí:Biological control of a univoltine race of European corn borer, Ostrinia nubilalis Hübner (Lepidoptera: Crambidae), by Trichogramma in Switzerland is currently timed according to repeated, semi‐field observations of the post‐diapause development of the pest at one site. We developed a phenology model with the aims of replacing this costly labour practice and by considering the Swiss landscape. Observations collected over 29 years were used for model calibration and validation. We parameterized a time‐varying distributed delay model based on published laboratory observations of development durations at constant temperatures. The model was driven with hourly temperature recordings beginning on January 1. The calibration of the mean development rates and their variations was based on semi‐field data of larval and pupal development. The model, with its calibrated parameters and their variations, allowed the simulation of mean predictions and prediction intervals. We validated the model predictions of emergence with flight data (obtained via light traps) from several sites in western and northern Switzerland. The simulated mean emergence was 6.9 degree‐days earlier than the observed flight at the calibration sites and only 0.5 degree‐days earlier than the observed flight at other sites. Our simulation of pupation explained half of the variation in emergence time, whereas semi‐field observations of pupation explained three‐quarters of this variation. Our model simulations are not subjected to the local potential biases. Simulation errors from a year with an extremely dry spring were explained by the lack of consideration of humidity by the model. Our simulations provide a valid and less labour‐intensive alternative to observations for timing biological control in the maize‐growing areas of Switzerland and likely other areas of Europe.
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ISSN:0931-2048
1439-0418
DOI:10.1111/jen.12364