DARPA AI Algorithms Transition from Simulator to Flying Modified F-16
A joint Department of Defense team executed 12 flight tests in which artificial intelligence (AI) agents piloted the X-62A Variable Stability In-Flight Simulator Test Aircraft (VISTA) to perform advanced fighter maneuvers at Edwards Air Force Base, California, Dec. 1-16, 2022. Supporting organizations included the U.S. Air Force Test Center, the Air Force Research Laboratory (AFRL) and the Defense Advanced Research Projects Agency (DARPA).
VISTA was developed by Lockheed Martin Skunk Works in collaboration with Calspan Corporation for the U.S. Air Force Test Pilot School (USAF TPS). VISTA is a modified F-16D Block 30 Peace Marble Il aircraft upgraded with Block 40 avionics.
Built on open systems architecture, VISTA is fitted with software that allows it to mimic the performance characteristics of other aircraft. Recent upgrades by the U.S. Air Force include an updated VISTA Simulation System (VSS) provided by Calspan, and Lockheed Martin's Model Following Algorithm (MFA), and System for Autonomous Control of the Simulation (SACS). The SACS and MFA systems integrated together provide new capabilities to the VISTA so it can be used to conduct the most advanced flight test experiments emphasizing autonomy and AI.
This new mission system capability with VSS, MFA and SACS emphasize advancing autonomous aircraft algorithm development and integration. At the heart of SACS system is the Skunk Works Enterprise-wide Open Systems Architecture (E-OSA) which powers the Enterprise Mission Computer version 2 (EMC2) or "Einstein Box."
Additional SACS components include integration of advanced sensors, a Multi-Level Security solution, and a set of Getac tablet displays in both cockpits. These components enhance VISTA's capabilities while maintaining its rapid-prototyping advantage, specifically allowing for quick software changes to increase the frequency of flight test flights and accelerating the pace of AI and autonomy development to meet urgent national security needs.
During the tests, AFRL’s Autonomous Air Combat Operations (AACO) and DARPA’s Air Combat Evolution (ACE) AI-driven autonomy agents piloted the X-62A to perform advanced fighter maneuvers. AACO’s AI agents performed one-on-one beyond-visual-range, or BVR, engagements against a simulated adversary, and ACE’s AI agents performed within-visual-range maneuvering, known as dogfighting, against constructive AI red-team agents.
Both teams’ AI agents executed autonomous tactical maneuvering while maintaining real-world airspace boundaries and optimizing aircraft performance. These tests are built upon the X-62A VISTA upgrade, which allows the X-62 to be controlled by AI-driven autonomy algorithms and mimic flight characteristics of fixed-wing vehicles such an MQ-20 or as in these tests, an F-16.
In several instances, pilots completed the tests for ACE and AACO within hours of each other after engineers switched autonomy algorithms onboard the X-62A in minutes.
“The X-62A is rapidly accelerating the speed at which autonomy algorithms are tested,” said an official familiar with the experimentation. “The X-62A VISTA Gen2020 upgrade transformed the NF-16D VISTA into the X-62A VISTA to support autonomy testing such as this test campaign."
The official said the rapid changes that can be achieved safely on VISTA allow researchers to respond to lessons learned quickly, improving capabilities during test windows.
“The X-62A VISTA team has proven with this test campaign that they are capable of complex AI test missions that accelerate the development and testing of autonomy capabilities for the DOD,” said Dr. Malcolm Cotting, the director of Research for the U.S. Air Force Test Pilot School.
Cotting said the VISTA team will continue to support rapid advanced autonomy tests and push the state-of-the-art in flight testing.
“The X-62 is a flight test accelerator,” the experimentation official said. “It allows the USAF to rapidly execute tactical autonomy algorithm and fixed-wing vehicle model flight tests. These tests generate data that is used to improve the algorithms and vehicle models at a remarkably fast pace,” he added. “The X-62 illustrates the value of using crewed, surrogate vehicles that possess tactical performance characteristics as autonomy test assets.”
The experimentation official said the joint team will continue leveraging the X-62 to test and evaluate autonomy capabilities and uncrewed vehicle models.
“After training our AI-driven autonomy agents using high performance computing and modeling and simulation, it is critical that we fly these agents to validate the difference from the simulator to live flights,” said an AACO official. “Having an aircraft like the X-62 is critical to rapid flight testing of these autonomous behaviors.”
The design of the X-62’s safety trip system is key to accelerating autonomy test, the AACO official added. The AACO team can fly, test and update agents based on flight data and then rapidly fly the new AI agents again within hours, without encountering airworthiness or safety issues.
“Across all domains, research moves only as fast as the tools permit,” said Lt. Col. Ryan Hefron, DARPA ACE program manager. “VISTA’s recent upgrade makes it a much more effective test bed by enabling rapid integration and safe testing of AI-driven autonomy. It allowed us to accelerate full-scale flight test of AI-driven autonomy by at least a year,” he said.
AACO and ACE are autonomy programs focused on developing AI-driven autonomy for airborne tactical platforms. The goal of AACO is to develop and fly an advanced AI-driven autopilot capable of performing aviate and navigate functions and autonomous behaviors such as advanced intelligence, surveillance and reconnaissance and BVR combat.
DARPA’s ACE program aims to develop trusted, scalable, human-level, AI-driven autonomy for air combat by using human-machine collaborative dogfighting as its challenge problem.
Both programs recognize the value and need for the X-62 and similar testbeds, which are critical for the maturation of AI-driven autonomy capabilities and new uncrewed vehicle model designs, the experimentation lead said.
Top Stories
INSIDERAR/AI
This Robot Dog Detects Nuclear Material and Chemical Weapons
Technology ReportEnergy
INSIDERDesign
New Anduril, Skydio Drones Start Field Testing in Romania
INSIDERTest & Measurement
Testing the Viability of Autonomous Laser Welding in Space
PodcastsUnmanned Systems
The Unusual Machines Approach to Low-Cost Drones and Drone Components
INSIDERAR/AI
Webcasts
Power
Designing an HVAC Modeling Workflow for Cabin Energy Management...
Aerospace
Countering the Evolving Challenge of Integrating UAS Into...
Defense
Best Practices for Developing Safe and Secure Modular Software
Robotics, Automation & Control
How Pratt & Whitney Uses a Robot to Help Build Jet Engines
Power
Scaling Manufacturing and Production for 'Data as a Service' Electric Drone
Test & Measurement
A Quick Guide to Multi-Axis Simulation and Component Testing