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$300K grant continues remote-sensing researchRIT recently won a $300,000 National Science Foundation grant to translate
remote-sensing data about wildfires into real-time “mini-movies”
that fire managers can download on laptop computers at the scene of a
blaze. The model and visualization will predict the fire’s “behavior”
for the following hour. This four-year collaborative project also involves researchers from the
National Center for Atmospheric Research in Boulder, Texas A&M, University
of Colorado at Denver and University of Kentucky. Leading RIT’s research effort is Anthony Vodacek, assistant professor
in the Chester F. Carlson Center for Imaging Science. Vodacek also leads
RIT’s Forest Fire Imaging Experimental System (FIRES), a precursor
to the Wildfire Airborne Sensor Program (WASP). Other team members will
include CIS senior research scientist Robert Kremens and postdoctoral
fellow Ambrose Ononye. FIRES and WASP research were made possible through the efforts of Congressman
Jim Walsh, chair of the House VA/HUD Independent Agencies Appropriations
Subcommittee, who has provided nearly $8 million through the NASA budget
over four years to support fire detection research at RIT. The RIT team has two roles in its new project: first, it will collect
real-time data about wild fires using the airborne sensor WASP and ground-based
sensors; and, second, it will use computer animation to visualize predicted
fire behavior. In between those two steps, is a unique fire behavior model that forms
the core of the project. Information collected by the RIT team will be
fed into the model created by Vodacek’s colleague Janice Coen at
NCAR and based on fire-behavior models in use by the U.S. Forest Service.
Coen’s model will combine RIT’s data with the influence of weather
conditions. The model will output a 3-dimensional “movie” about
the fire that will be sophisticated enough to predict dangerous fire behavior,
such as leaping flames. Other members of the collaborative team will be in charge of feeding
a wide variety of raw data to the model and sending it back to the fire
scene in as close to real time as possible. In order for this relay of information to be successful, Vodacek will
need to make the scientific data meaningful to the fire fighters. “Coen’s model can track smoke and hot gases in the atmosphere,”
he says. “We need to translate that into what a fire looks like by
using computer animation. It fits very well into what we’ve been
doing in the FIRES project. My graduate student Zhen Wang has been developing
synthetic remote sensing scenes that include fire.” Vodacek’s team will create synthetic scenes of fires to visualize
live blazes based on Coen’s model, which will tell them where flames
will be in any particular situation. “We would translate it into what a person would see,” Vodacek
says. “Essentially, a little movie would be generated. In the end,
the goal is to make it look real to the fire manager.” The process will work like this: overhead and ground sensors will collect
real-time data about a fire to feed into the model. The data will be transferred
to a super computer where the model is run and then sent back to the field.
The fire could be in Montana and the super computer in Georgia, Vodacek
notes. The link is the laptop that the fire manager will use to watch
how the fire is predicted to behave for about an hour. “The idea is that all of this will occur as close as possible to
real time,” Vodacek says. “By the time it takes to collect the
data, run it through the model and send it back to the field, it may be
15 minutes old. But, still, that gives you a 45-minute outlook, potentially.” The overall goal of the project is to demonstrate the entire system at the end of four years. |
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