R³ Engineering (R³E) recently completed a demonstration of an ADS-B (Automatic Dependent Surveillance–Broadcast) based, fully autonomous collision avoidance sequence, executed by a sense and avoid system installed on an unmanned aircraft system (UAS).
On Friday Aug. 10, an AWSAS — R³E’s All Weather Sense and Avoid System — installed on a research UAS, with no external command or control inputs, commanded the UAS’s auto-pilot to depart from its programmed flight path, execute an internally computed maneuver to avoid a potential collision, and then return to the original planned flight path when well clear of the intruder, company officials said.
ADS-B messages received and processed by the AWSAS’ internal computer indicated that the aircraft was on a collision course with another ADS-B equipped target. The AWSAS’ embedded Sense And Avoid (SAA) algorithm analyzed the flight tracking data; determined that a potential breach of the aircraft’s “collision volume” was imminent; determined an optimum collision avoidance maneuver; and sent commands directly to the autopilot, company officials explained.
The UAS’s auto-pilot responded to the commands, turning the aircraft away from the intruder; and, when clear of the conflict, returned the aircraft to its preprogrammed flight path. This entire sequence was autonomous, with no command or control inputs from outside the unmanned aircraft.
The autonomous flight test was conducted at the former Naval Base in Argentia, Newfoundland, in cooperation with Memorial University of St. John’s Newfoundland, following a series of flight tests that took place in Florence, Ariz., San Diego, and Grand Forks, N.D. The tests are demonstrating the ADS-B based AWSAS’ capability to develop target tracks from data it receives, project potential conflicts at a future time, compute and recommend to the ground-based remote pilot maneuvers such as course or speed change that will maintain safe separation; and if absolutely necessary, send collision avoidance maneuvers directly to the aircraft autopilot, according to company officials.
The test series included potential collision scenarios between the UAS and stationary hazards, moving ground hazards, and between two UAS aircraft.
The flight test series is scheduled to expand with testing later this year in Restricted Airspace that will incorporate non-cooperative target data from sensors such as radar and EO/IR into the AWSAS’ SAA process.
Development and initial testing of the AWSAS prototypes has been funded by the Office of Naval Research, the Department of Defense’s DSOC (Defense Safety Oversight Council) Aviation Safety Technologies program, and NAVAIR.
The AWSAS, a combination of Field Programmable Gate Array and Digital Signal Processor technologies, has been developed by R³E with funding from the Office of Naval Research. The program started in 2009; and the AWSAS hardware is manufactured by Appareo Systems of Fargo, North Dakota. The AWSAS weighs less than 1 pound, and is a low cost, open-architecture, dual band (1090 MHz-in and 978 MHz-in/out) ADS-B radio, coupled with a digital processing capability that develops tracks from received target data, computes maneuvers necessary to maintain safe separation between own aircraft and other aircraft or obstacles, and, when necessary, directly commands an autopilot to maneuver to avoid a collision, company officials said..
Part of AWSAS’ 978 MHz Universal Access Transceiver (UAT) is based on a licensed MITRE design that has been upgraded to the current configuration. The system can simultaneously monitor many targets – in simulations, as many as 200 contacts were simultaneously tracked and analyzed for potential loss of safe separation – and computes optimum separation maneuvers to avoid creating new conflicts while avoiding one, officials continued. Data logging is included for post-flight analysis and/or replay.
In addition to “moving” targets such as other aircraft, AWSAS can store “non-moving” obstacle information such as terrain data, locations of wires and towers and tall buildings, along with “virtual obstacle” information such as “no fly” zones and international borders that should not be crossed. The AWSAS’s ADS-B cooperative target capability covers approximately 95% of all aircraft, officials note. The AWSAS also receives weather and traffic information that is broadcast as part of the FAA’s NextGEN air traffic management system.
R³ Engineering, LLC, was founded in 2009 and is based in Lusby, Maryland. The AWSAS is R³E’s first product and was developed for the purpose of enabling unmanned aircraft to safely operate in cooperative airspace; and when augmented by appropriate non-cooperative sensors, to operate safely in any airspace. R³E’s design for the AWSAS includes an open architecture that accepts SAA software from any source; and the ability to function on any platform, with any autopilot or any ground display. R³E will be conducting a webinar on Nov. 19 for anyone interested in discussing AWSAS technology.
For more information: 202-271-9686
