With Unmanned Aircraft System (UAS) operations rapidly growing worldwide, there is a significant need to manage a variety of aircraft close to each other. This is particularly challenging in the lower airspaces around airports, which have long been used solely by commuter aircraft.

Urban Air Mobility (UAM) programs are taking shape, and developments from ongoing flight tests are pushing the limits of existing air traffic management systems. In the United States, several UAS operators have received their Part 135 air carrier certificates that enable them to perform payload-carrying commercial operations.

Airbus envisions that in the near future, thousands of aircraft will be populating low-level airspace across worldwide locations. Low-level airspace is generally defined as from the surface to approximately 3,000 ft (914 m) above mean sea level. The Federal Aviation Administration (FAA) describes the low-level airspace as Class D airspace - generally from the surface to 2,500 feet (762 m) above the airport elevation.

Aircraft must establish two-way radio communications with the Air Traffic Control (ATC) facility providing air traffic services before entering any airspace and subsequently maintain communication within the airspace.

Future aircraft will include helicopters, air taxis, delivery drones, and eVTOL aircraft. But, commuter airplanes already use lower airspace, particularly during climb and approach. The introduction of UAS in already-populated lower airspace, especially around busy airports, creates new challenges for Air Traffic Management (ATM).

Airbus and Boeing jointly released a document “A New Digital Era of Aviation: The Path Forward for Airspace and Traffic Management” to demonstrate Unmanned Traffic Management (UTM) and its use in future airspace and traffic management. The document states,

"Today’s UAS operations are limited or restricted in many types of airspace to keep them away from manned aircraft. UTM will facilitate safe integration while ensuring the increasing number and complexity of UAS missions are appropriately coordinated and routed. The need for UTM becomes even greater for uses such as urban air mobility, which include complex on-demand passenger-carrying operations in busy areas."

Existing challenges

One of the most significant challenges is balancing the requests of two different types of vehicles in flight that are in conflict with each other. Interactions between UAS and traditional aircraft must be resolved during flight and will depend on several constraints, including environmental effects, security, and privacy. The management of such interactions requires proper allocation of resources.

A successful flight is a team effort.
Photo: ersin ergin I Shutterstock

Existing ATM systems require implementing those tailored for UAS, which ensures the compatibility of both traffic management systems. ATM and UTM alignment and integration require a complete understanding of both ecosystems, from products to procedures, systems, and human factors. A robust air traffic management infrastructure must be in place to safely manage various air vehicles.

Unmanned Traffic Management (UTM)

Airbus has established an Unmanned Traffic Management (UTM) system that will provide digital air traffic management solutions for the future of aviation. The UTM infrastructure is expected to offer digital and automated services which can pave the way for new capabilities and concepts of operation while working alongside and converging with current ATM advancements.

"The system must be interoperable across countries, and compatible with ATM upgrades meaning the development of relevant global standards is of high importance. This is both a challenge and an opportunity, for regulators and authorities as traffic management evolves. Industry can play a greater role in helping to address these challenges, and in turn, help realize the benefits arising from ongoing innovation across the aviation sector."

The UTM design team is keen to build on the existing air traffic management infrastructure to allow space for future vehicles. According to Airbus,

"Airbus UTM teams design, develop and build the enabling infrastructure necessary to allow existing aircraft to continue operating in lower airspace and future vehicles, including delivery drones and air taxis, to safely enter and share our future skies. Through the UTM program, Airbus aims to ensure that overall system design considerations around safety, security, reliability, and interoperability (among others) are not compromised by a desire to deploy UTM systems as quickly or inexpensively as possible."

The guiding principles of the International Civil Aviation Organization (ICAO) suggest that airspace access should remain equitable among all stakeholders. Airbus’ UTM design ensures a system that guarantees fair access to all users. The distribution of delay across operators, driven by traffic density, must be handled fairly.

Framing the UTM infrastructure

Airbus collaborates with regulators, manufacturers, service providers, and Urban Air Mobility (UAM) end-users to establish a common understanding of future airspace. Several use cases related to the interactions between air vehicles are simulated to demonstrate vehicle-specific requirements. The allocation of UTM resources is driven based on air vehicle requirements and environmental constraints to offer a fair, secure, and robust UTM infrastructure.

According to Airbus,

ATM and UTM alignment and integration require a full understanding of both ecosystems from products to procedures, systems, and human factors.

The deployment of a comprehensive framework with services for flight authorization and authoritative data is possible through Airbus’ UTM platform. The safety and performance of the new UTM infrastructure are at the forefront of Airbus’ UTM team. The technology team conducts 4G and 5G network trials to evaluate safety and performance.

Moreover, the handling of two-way communication between aircraft, including unmanned ones, and the controller must be failsafe. The UTM team analyzes safety-critical communications within real-world environments in low-level airspace. Safety is ensured through multiple redundancies at the design (hardware) and technological (software) levels.

An Etihad Airbus A380-861, registration A6-APF, pulling up to an airport stand.
Photo: Vincenzo Pace | Simple Flying.

Airbus is taking a holistic approach, combining ATM and UTM, to build the air traffic control infrastructure needed for future operations. The amalgamation of the two networks will allow the seamless integration of unmanned aerial vehicles (UAVs) into the existing airspace.

The new UTM system will be compatible with the updated ATM network, enhancing the social acceptance of UAVs. Airbus and its industry partners also aim to assess solutions based on human factors, as it is one of the critical parameters for safe air traffic management operations.

What are your thoughts on a robust infrastructure for future air traffic management and Airbus’ UTM initiative? Tell us in the comments section.