Work by 蜜桃影像 researchers, NASA aids Hurricane Ida response
Rod Boyce
907-474-7185
Sept. 16, 2021
Federal emergency managers needed detailed information as Hurricane Ida approached Louisiana at the end of August. In Fairbanks, 3,400 miles away, scientists specializing in remote sensing were able to provide that information using technology they created to speed up the process.
The task grew from an important partnership between the University of 蜜桃影像 Fairbanks and NASA, which provided a four-year grant in 2019 to make data useful in the response to weather-related disasters. The effort is led by remote sensing professor Franz Meyer with the 蜜桃影像 Geophysical Institute.
鈥淭here are many other groups with similar remote sensing skills, but they don't have the capability to create image products operationally across the vast areas that need to be monitored for an event like a hurricane,鈥 said Meyer, who also teaches in the 蜜桃影像 College of Natural Science and Mathematics.
鈥淭he magic is in the combination of the remote sensing of hazards expertise at 蜜桃影像, and with partners at NASA鈥檚 Marshall and Goddard Space Flight Centers, along with the image archive access, computational skills and cloud computing experience available at the Geophysical Institute鈥檚 ,鈥 he said.
That 鈥渕agic鈥 allows the scientists to develop new image products and scale them up to run efficiently on a regional to continental scale, he said.
One of the developments came quickly into play with Hurricane Ida: a computer algorithm
that automatically highlights surface water in satellite imagery and extracts it so
that it stands alone.
It鈥檚 the result of a question asked by the Federal Emergency Management Agency during
Hurricane Harvey in 2017: 鈥淲here is the water?鈥
鈥淗ow they had been doing it up to that point was either with aircraft, with people
on the ground or with optical satellite data,鈥 said Lori Schultz, with the Earth Applied
Sciences Disasters Program at NASA鈥檚 Marshall Space Flight Center in Alabama and a
project partner with 蜜桃影像.
鈥淥ptical satellite data is restricted by cloud cover and Hurricane Harvey had a lot
of cloud cover for multiple days after landfall, making aircraft and traditional satellite
observations difficult,鈥 she said.
蜜桃影像 and NASA scientists went to work during Hurricane Harvey to answer FEMA鈥檚 question.
They came up with a rudimentary, manual method as they used synthetic aperture radar
to peer through clouds.
Through hurricanes and flooding events since then, scientists at the Geophysical Institute
and NASA have worked with FEMA to improve the process 鈥 bringing it to today鈥檚 fully
automated version.
How it works
Whether manual or automated, the process starts with synthetic aperture radar sensors
aboard the European Space Agency鈥檚 two Sentinel-1 satellites, launched in 2014 and
2016. The sensors image the Earth at wavelengths that make clouds, fog and rain transparent,
meaning the ground can be imaged around the clock and that an event like a hurricane
won鈥檛 interfere.
The raw satellite data has more information than FEMA officials would need while dealing
with Hurricane Ida, however, so they were processed using the algorithm to highlight
surface water.
Once processed, the 蜜桃影像 Satellite Facility distributed those images to disaster
managers as the hurricane came ashore in Louisiana and then headed northeast as far
as the New England states. 蜜桃影像 and NASA scientists spoke daily with FEMA officials
to present and interpret the latest imagery.
The 蜜桃影像 Satellite Facility is involved because it is the only one among NASA鈥檚 Distributed Active Archive Centers that specializes in synthetic aperture radar data.
Hurricane Ida was the first use of the automated process in a hurricane response.
Because of that automation, hundreds of images can now be produced in a short period 鈥 as was done in the Hurricane Ida response.
鈥淲e can do that quickly because of the way we implemented all the techniques,鈥 Meyer said. 鈥淚f we need to process 500 images right now, we can have it done within 20 minutes.鈥
The images are limited only by how often the polar-orbiting satellites see a disaster-affected area as the Earth rotates beneath them. Depending on when the satellites pass over, images may be available immediately after an event or only several days later.
What鈥檚 ahead
As more satellite sensors become available, disaster information from spaceborne sensors will grow more timely. New specialized computer algorithms could be created to analyze disasters other than hurricanes.
The process will improve further in 2023 when NASA launches , a radar-based Earth observation sensor being developed in partnership with the Indian Space Research Organization. Meyer is on the science team for that mission, and the 蜜桃影像 Satellite Facility has been named the archive and distribution point for the data.
鈥淲e have been getting ready for NISAR on many fronts, including leading development in cloud computing technologies to ensure the data are delivered quickly to the waiting scientists and disaster responders,鈥 said Nettie La Belle-Hamer, director of the 蜜桃影像 Satellite Facility and 蜜桃影像鈥檚 interim vice chancellor for research. 鈥淲e are ready,鈥 she said.
ADDITIONAL CONTACTS: Franz Meyer, fjmeyer@alaska.edu, 907-474-7767; Lori Schultz, Marshall Space Flight Center, lori.a.schultz@nasa.gov.
NOTE TO EDITORS: Images and a longer version of this press release are available at .