Here’s What You Need to Remember: “Military pilots receive key information about their surroundings when teamed aircraft with integrated autonomy detect potential air and ground threats, determine threat proximity, analyze imminent danger, and identify suitable options for striking or evading enemy aircraft,” an Air Force Research Laboratory fact sheet says of Skyborg.
The Air Force Research Lab (AFRL) is flying autonomous drones able to navigate uneven, rigorous terrain, independently find and transmit target specifics, perform manned-unmanned teaming missions and operate a large number of functions without needing pilot control. Newer applications of software, hardware and computing could also possibly lead to unmanned-unmanned teaming. In such an environment, autonomous drones would operate swarms designed to blanket an area with surveillance, test enemy air defenses, find targets over high-threat areas and perhaps themselves function as mini-explosives.
Thus, a growing mission would be enhanced by the service’s emerging Skyborg Autonomy Core System program, a suite of integrated sensing, computing and payload technologies engineered for greater operational autonomy and manned-unmanned systems. Following a successful first flight in April 2021 on board a Kratos UTAP-22 drone, the Air Force Research Laboratory recently conducted a second flight with Skyborg ACS on a General Atomics MQ-20 Avenger.
The flight, which took place at Edwards Air Force Base, California, is part of a critical AFRL prototyping effort to introduce new levels of autonomy into air w4r. This will allow military personnel to expand the scope of their mission.
Humans will maintain supervisory command and control to ensure any use of lethal force is decided upon by a human pilot and in accordance with the military’s doctrine. However, Skyborg ACS will introduce breakthrough levels of autonomy enabling drones to perform a much wider sphere of operations without needing each individual action directed by a human.
“Military pilots receive key information about their surroundings when teamed aircraft with integrated autonomy detect potential air and ground threats, determine threat proximity, analyze imminent danger, and identify suitable options for striking or evading enemy aircraft,” an Air Force Research Laboratory fact sheet says of Skyborg. “The program will enable airborne combat mass by building a transferable autonomy foundation for a family of layered, unmanned air vehicles.”
Skyborg ACS is enabled by advanced computer algorithms engineered to gather, distill, organize, analyze, solve problems and ultimately streamline key data points of relevance to humans.
“Embedded within the teamed aircraft, complex algorithms and cutting-edge sensors enable the autonomy to make decisions based on established rules of engagement set by manned teammates,” the AFRL fact sheet states.
There are plans to expand field testing and development of Skyborg ACS to further ensure the algorithm’s accuracy and performance consistency. As testing and technical maturation continue to progress, the possibilities with a technology of this kind are quite significant. For many years now, aerial drones have been able to follow GPS-determined “waypoints,” however greater autonomy will likely enable drones to independently adjust to new information such as target movements or emerging terrain obstacles. This decreases the procedural functions human pilots need to perform, therefore moving toward establishing an optimal blend of man and machine in combat.