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NASA Supports Wildland Fire Technology Demonstration
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Editorβs Note: This article was updated April 16, 2025, to reflect the March 26 start date of NASAβs Alta X flights and provide additional details about the data collected.
Advancements in NASAβs airborne technology have made it possible to gather localized wind data and assess its impacts on smoke and fire behavior. This information could improve wildland fire decision making and enable operational agencies to better allocate firefighters and resources. A small team from NASAβs Armstrong Flight Research Center in Edwards, California, is demonstrating how some of these technologies work.
Two instruments from NASAβs Langley Research Center in Hampton, Virginia β a sensor gathering 3D wind data and a radiosonde that measures temperature, barometric pressure, and relative humidity data β were installed on NASA Armstrongβs Alta X drone for a prescribed burn in Geneva State Forest, which is about 100 miles south of Montgomery, Alabama. The effort is part of the agencyβs multi-year FireSense project, which is aimed at testing technologies that could eventually serve the U.S. Forest Service as well as local, state, and other federal wildland fire agencies.
βThe objectives for the Alta X portion of the multi-agency prescribed burn include a technical demonstration for wildland fire practitioners, and data collection at various altitudes for the Alabama Forestry Commission operations,β said Jennifer Fowler, FireSense project manager. βInformation gathered at the different altitudes is essential to monitor the variables for a prescribed burn.β
Those variables include the mixing height, which is the extent or depth to which smoke will be dispersed, a metric Fowler said is difficult to predict. Relative humidity must also be above 30% for a prescribed burn to meet requirements in Geneva State Forest. The technology to collect these measurements locally is not readily available in wildland fire operations, making the Alta X and its instruments key in the demonstration of prescribed burn technology.
In addition to the Alta X flights beginning March 26, NASA Armstrongβs B200 King Air will fly over actively burning fires at an altitude of about 6,500 feet. Sensors onboard other aircraft supporting the mission will fly at lower and higher altitudes before, during, and after the fire for required data collection. The multi-agency mission will provide data to improve models to better predict fire behavior and effects, including smoke lofting, trajectory, and dispersion.
Small, uncrewed aircraft system pilots from NASA Armstrong completed final preparations to travel to Alabama and set up for the research flights. The team β including Derek Abramson, chief engineer for the subscale flight research laboratory; Justin Hall, NASA Armstrong chief pilot of small, uncrewed aircraft systems;Β and Alexander Jaffe, a drone pilot β will set up, fly, observe airborne operations, all while keeping additional aircraft batteries charged. The launch and recovery of the Alta X is manual, the mission profile is flown autonomously to guarantee the same conditions for data collection.
βThe flight profile is vertical β straight up and straight back down from the surface to about 3,000 feet altitude,β Abramson said. βWe will characterize the mixing height and changes in moisture, mapping out how they both change throughout the day in connection with the burn.β
In August 2024, a team of NASA researchers used the NASA Langley Alta X and weather instruments in Missoula, Montana, for a FireSense project drone technology demonstration. These instruments were used to generate localized forecasting that provides precise and sustainable meteorological data to predict fire behavior and smoke impacts.
