Artificial neural networks for automated year-round temperature prediction

Crops and livestock in most of the southeastern United States are susceptible to potential losses due to extreme cold and heat. However, given suitable warning, agricultural and horticultural producers can mitigate the damage of extreme temperature events. To provide such a warning, air temperature...

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Bibliographic Details
Published in:Computers and electronics in agriculture 2009-08, Vol.68 (1), p.52-61
Main Authors: Smith, Brian A., Hoogenboom, Gerrit, McClendon, Ronald W.
Format: Article
Language:English
Subjects:
accuracy
Agronomy. Soil science and plant productions
air temperature
Artificial intelligence
Biological and medical sciences
climate models
cloud cover
cold stress
data analysis
decision support systems
environmental monitoring
Frost protection
Fruit crops
Fundamental and applied biological sciences. Psychology
heat stress
information dissemination
meteorological data
Neural network
neural networks
prediction
rain
risk management
simulation models
Temperature prediction
Vegetable crops
world wide web
www.GeorgiaWeather.net
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Summary:Crops and livestock in most of the southeastern United States are susceptible to potential losses due to extreme cold and heat. However, given suitable warning, agricultural and horticultural producers can mitigate the damage of extreme temperature events. To provide such a warning, air temperature prediction models are needed at horizons ranging from 1 to 12 h. The goal of this project was to explore the application of artificial neural networks (ANNs) for the prediction of air temperature during the entire year based on near real-time data. Ward-style ANNs were developed using detailed weather data collected by the Georgia Automated Environmental Monitoring Network (AEMN). The ANNs were able to provide predictions throughout the year, with a mean absolute error (MAE) of the year-round models that was less during the winter months than the MAE of the models resulting from the application of previously developed winter-specific models. The prediction MAE for a year-round evaluation set ranged from 0.516 °C at the one-hour horizon to 1.873 °C at the twelve-hour horizon. A detailed graphical analysis of MAE by time-of-year and time-of-day was also performed. A tendency to over-predict temperatures during summer afternoons was associated with localized cloud cover during that period. The inclusion of rainfall as input to the model was also shown to improve prediction accuracy. In addition, two simple ensemble techniques were explored and neither parallel nor series aggregation was found to reduce prediction errors. When simulated over two extreme temperature events, the models were capable of rapidly adjusting predictions on the basis of new information. The final models were applied to prediction horizons of 1–12 h and deployed on the website of the Georgia AEMN ( www.GeorgiaWeather.net) for use as a general, year-round decision support tool.
ISSN:0168-1699
1872-7107
DOI:10.1016/j.compag.2009.04.003