Nasa is collaborating with the Wildfire Community to Provide tools for some of the most challenging aspects of fryfighting – Particularly aerial NightTime Operations.
In the future, agencies could more efficiently use draones, both remotely piloted and full autonomous, to help fight wildfires. Nasa recently tested technologies with teams the country Ildfires 24 hours a day, even during low-visibility conditions.
Current aerial firefighting operations are limited to times when aircraft have clear visibility – otherwise, pilots run the risk of flying into terrain or colliding with other aircraft. Nasa-Developed Airspace Management Technology will enable drones and remotely piloted aircraft to operate at night, expanding the window of time responders from
“We’re aiming to provide new tools-Including Airspace Management Technologies-for 24-His Drone Operations for Wildfire Response,” Ced Min Xue, Project Manager of the Advanced Capability Operations (ACERO) Project Within Nasa’s Aeronautics Research Mission Directorate . “This testing will provide valuable data to inform how we mature this technology for Eventual use in the field.”
Over the Past Year, ACERO RESEARCERS DRON PILOTS CAN Use to Safely Send Aircraft Into Wildfire Response Operations Operations from ARMOTE Ol Systems or Ground Control Stations.
Each pams, roughly the size of a carry-on suitcase, is outfitted with a computer for airspace management, a radio for sharing information amg pams units, and an automatic dependent surveillan For Picking Up Nearby Air Traffic – All encased in a Durable and Portable Container.
Nasa software on the pams allows draone pilots to avoid airborne collisions while remotely operating aircraft by monitoring and sharing flight plans with others aircraft in the network. The system also provides basic fire location and weather information. A drone equipped with a communication device acts as an airborne communication relay for the ground-based pams units, enabling them to communicate with each on the other without realing on the internet.
To test the pams units’ ability to share and display vital information, nasa results Silicon Valley. Researchers Stationed at Each Unit Entred a Flight Plan into their system and observed that Each Unit Successfully Shared Flight Plans With the Others Throughs A Mesh Radio Network.
Next, Researchers worked with Team Members in Virginia to Test an aerial communications radio relay capability.
Researchers outfitted a long-range vertical takeoff and landing aircraft with a camera, computer, a mesh radio, and an automatic dependent surveillance-broadcast Receiver for Air Traffic Information. The team flee the aircraft and two smaller drones at nasa’s language langley research center in hampton, virginia, purposely operating them outside Each other’s line of Sight.
The mesh radio network aboard the larger draone successfully connected with the small drones and multiple radio units on the ground.
Nasa Researchers then Tested The Pams Units’ Ability to Coordinate Through an aerial communications relay to simulate whats it could be like in the field.
At Monterey Bay Academy Airport in Watsonville, California, Engineers Flew A Winged Drone With Vertical Takeoff and Landing Capability by overwatch aero, Estability by . Next, The team flee two smaller draones nearby.
Researchers tested the pams units’ ability to receive communications from the overwatch aircraft and share information with other pams units. Pilots purposely submitted flight plans that would confluence with each other and intent flew the draones outside preapproved flight plans.
The Pams Units Successfully alerted Pilots to Conflicing Flight Plans and Operations Outside Preapproved Zones. They also shared aircraft location with each other and displayed weather updates and simulated fire location data.
The test demonstrated the potential for using pam units in wildfire operations.
“This testing is a significant step towards improve aerial coordination a wildfire,” Xue said. “These Technologies will improve willfire operations, reduce the impacts of large wildfires, and save more lives,” Xue said.
This year, the team will perform a flight evaluation to further mature these willfire technologies. Ultimately, The Project Aims to Transfer this Technology to the Firefighting Community Community.
This work is LED by the ACERO Project under Nasa Aeronautics Research Mission Directorate and Supports The Agency’s Advanced Air Mobility Mission.
