Researchers have used artificial intelligence to predict where flood damage is likely to happen in the continental United States.
The findings suggest that recent flood maps from the Federal Emergency Management Agency do not capture the full extent of flood risk.
In the study, researchers found a high probability of flood damage—including monetary damage, human injury and loss of life—for more than a million square miles of land across the United States across a 14-year period.
That was more than 790,000 square miles greater than flood risk zones identified by FEMA’s maps.
“We’re seeing that there’s a lot of flood damage being reported outside of the 100-year floodplain,” says Elyssa Collins, a doctoral candidate in the North Carolina State University Center for Geospatial Analytics and lead author of the Environmental Research Letters paper.
“There are a lot of places that are susceptible to flooding, and because they’re outside the floodplain, that means they do not have to abide by insurance, building code and land-use requirements that could help protect people and property.”
Machine Learning Flood Models
It can cost FEMA as much as $11.8 billion to create national Flood Insurance Rate Maps, which show whether an area has at least a 1 percent chance of flooding in a year, according to a 2020 report from the Association of State Floodplain Managers. Researchers say their method of using machine learning tools to estimate flood risk offers a way of rapidly updating flood maps as conditions change or more information becomes available.
“This is the first spatially complete map of flood damage probability for the United States—wall-to-wall information that can be used to learn more about flood risk in vulnerable, underrepresented communities,” says Ross Meentemeyer, professor of geospatial analytics.
To create their computer models, researchers used reported data of flood damage for the United States, along with other information such as whether land is close to a river or stream, type of land cover, soil type and precipitation. The computer was able to “learn” from actual reports of damage to predict areas of high flood damage likelihood for each pixel of mapped land. They created separate models for each watershed in the United States.
“Our models are not based in physics or the mechanics of how water flows; we’re using machine learning methods to create predictions,” Collins says.
“We developed models that relate predictors—variables related to flood damage such as extreme precipitation, topography, the relation of your home to a river—to a dataset of flood damage reports from the National Oceanic and Atmospheric Administration. It’s very fast—our models for the U.S. watersheds ran on an average of five hours.”
The actual flood damage reports they used to “train” the models were publicly available reports from NOAA made between December 2006 and May of 2020.
Compared with recent FEMA maps downloaded in 2020, 84.5 percent of the damage reports they evaluated were not within the agency’s high-risk flood areas. The majority, at 68.3 percent, were located outside of the high-risk floodplain, while 16.2 percent were in locations unmapped by FEMA.
Stream Proximity, Elevation, Precipitation
When researchers ran their computer models to determine flood damage risk, they found a high probability of flood damage for more than 1.01 million square miles across the United States, while the mapped area in FEMA’s 100-year flood plain is about 221,000 square miles.
Researchers say there are factors that could help explain why the differences were so large, including that their machine-learning-based model assessed damage from floods of any frequency, while FEMA only includes flooding that would occur from storms that have a 1 percent chance of happening in any given year.
“Potentially, FEMA is underestimating flood damage exposure,” Collins says.
One of the biggest drivers of flood damage risk was proximity to a stream, along with elevation and the average amount of extreme precipitation per year. The three Census regions with the highest probability were in the Southeast. Louisiana, Missouri, the District of Columbia, Florida and Mississippi had the highest risk of any U.S. state or district in the continental United States. Of the 30 most high-risk counties, North Carolina had three: Dare, Hyde and Tyrrell.
In their model, researchers used historical climate data. In the future, they plan to account for climate change.
In the meantime, researchers say their findings, which will be publicly accessible, could be useful for helping policymakers involved in land-use planning. They also represent a proof-of-concept method for efficiently updating flood maps in the future.
“There is still work to be done to make this model more dynamic,” Collins says. “But it’s part of a shift in thinking about how we approach these problems in a more cost-effective and computationally efficient manner. Inevitably, with climate change, we’re going to have to update these maps and models as events occur. It would be helpful to have future estimates that we can use to prepare for whatever is to come.”
The U.S. Geological Survey Southeast Climate Adaptation Science Center and the North Carolina State University Sea Grant program funded the work.
This article originally appeared in Futurity, a source of research news for universities.
Photo (Janet Blackmon Morgan/The Sun News via AP)