Predicting extreme fire weather using artificial intelligence
Computer model inspired by human brain could help fire management agencies be better prepared for extreme conditions
Wildland fires can have devastating societal impacts and Canada spends up to $1 billion on fire management every year with costs continuing to rise. Developing tools that rapidly predict the potential for extreme fire weather can help fire management agencies ensure community safety by being better prepared and securing necessary resources.
A new study
published today in Canadian Journal of Forest Research
describes a computational model capable of learning that can be used to predict the occurrence of extreme fire weather in northern Alberta, Canada. Forest science researchers from the University of Oklahoma and the University of Alberta built and tested the model, referred to as a “self-organizing map” (SOM), using atmospheric pressure variables known to affect weather conditions. The model generates maps that predict where and when extreme fire weather is expected in northern Alberta.
“Most of the impacts from wildland fire happen during a short period of extreme fire weather that is hot, dry, and windy,” says Dr. Mike Flannigan, co-author of the study and professor at the University of Alberta. As real-time meteorological data is collected throughout Alberta’s fire season from May to August it can be inputted into this SOM model. The model then learns from the new data inputs and generates updated maps and predictions. This process suggests SOMs “could be used in day-to-day fire management and as part of an early warning system,” Flannigan adds.
Similar to the human brain, SOMs are described as an array of neurons that can be “trained” to find patterns in data and model complex relationships. SOMs are a type of machine learning system—an application of artificial intelligence whereby machines learn by themselves and not by direct programming. SOMs have been used previously to predict other weather events such as monsoons but this is the first study to use this technique for predicting extreme fire weather in real time.
For predicting fires, compared to simpler statistical models traditionally used, an SOM “may provide a better and more robust method to flag potential extreme fire-weather events,” the authors say because SOMs can handle spatial and temporal weather data that are not linearly related to wildfire traits such as intensity and growth rate.
Last year, the Fort McMurray fire in Alberta was responsible for nearly 90,000 people being evacuated, $3.77 billion in insurable losses and a drop in national GDP—the costliest natural disaster in Canadian history.
"I'm very impressed with what Dr. Flannigan and colleagues have accomplished through applying an advanced computational method like machine learning to the challenge of predicting extreme fire weather,” said Ellen Macdonald, chair of the Department of Renewable Resources in the Faculty of Agricultural, Life and Environmental Sciences at the University of Alberta. “This is a very important advancement that can help agencies pro-actively deploy fire-fighting resources to communities and is an excellent example of how research is the foundation for development of practical tools that benefit society."
The article, “Automated Prediction of Extreme Fire Weather from Synoptic Patterns in Northern Alberta, Canada
” by Ryan Lagerquist, Mike Flannigan, Xianli Wang, and Ginny Marshall was published today in Canadian Journal of Forest Research
Please cite Canadian Journal of Forest Research
as the source of this story and include a hyperlink to the research study: dx.doi.org/10.1139/cjfr-2017-0063
Natalie Sopinka, Communications Coordinator, Canadian Science Publishing
+1 613-656-9846 ext. 232, firstname.lastname@example.org
Dr. Mike Flannigan, Professor
Department of Renewable Resources, University of Alberta
+1 780-248-2033, email@example.com
About the Journal
Published since 1971, the Canadian Journal of Forest Research
is a monthly journal featuring articles, reviews, notes and concept papers on a broad spectrum of forest sciences, including biometrics, conservation, disturbances, ecology, economics, entomology, genetics, hydrology, management, nutrient cycling, pathology, physiology, remote sensing, silviculture, social sciences, soils, stand dynamics, and wood science, all in relation to the understanding or management of ecosystem services. It also publishes special issues dedicated to a topic of current interest.
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