Abstract
Recent electronics advances for air transport have increased aircraft density, volume, and frequency in the airspace. These advances come with control requirements for precise navigation, coordinated Air Traffic Management (ATM) or Unmanned aircraft system Traffic Management (UTM), and proactive security. The tight tolerances of aircraft control necessitate management of spatial uncertainty, timeliness precision, and confidence assessment, which have, respectively, variance, reliability, and veracity situation awareness and assessment metrics. Meeting such airspace requirements involves the ability to evaluate how those metrics impact ATM/UTM operations, making the complex interrelationships between them a key aspect for coping with the fast worldwide growth of air transport. To support such growth, ontologies have been proposed as a promising technology for making such interrelationships explicit, while facilitating communication between avionics devices. This paper investigates the use of ontologies in support of electronic ATM/UTM operations, highlighting the use of Uncertainty Representation and the Reasoning Evaluation Framework (URREF) in realizing the ability for Air Traffic Controllers (ATCs) to semantically communicate with aircraft operators concerning physical airspace coordination. Using Avionics Analytics Ontology (AAO) endowed with the URREF, application examples based on two airspace situations are presented. Example results for northeast coast of Brazil atmospheric volcanic ash as well as for the Eyjafjallajokull volcano eruption show a 65–80% success in providing warnings to ATCs for airspace control. The paper demonstrates that an ontology-based UTM enhances the capability and accuracy of an ATM to suggest rerouting in the presence of remarkably deteriorated weather conditions.
Highlights
The explosion of potential aerospace platforms, including unmanned aerial vehicles (UAVs), electric vertical take-off and landing aircraft, and autonomous air parcel delivery (AAPD) networks, requires advanced large-scale processing methods, such as ontological analytics
The integration of smart avionics includes the interaction between electronic equipment supporting Air Traffic Management (ATM), Unmanned Aerial Systems Traffic Management (UTM), and a Human–Machine Interface (HMI)
A reasoner is a cognitive engine for ontology queries that can be applie above Ontology Web Language (OWL)-described Analytics Ontology (AAO)
Summary
The explosion of potential aerospace platforms, including unmanned aerial vehicles (UAVs), electric vertical take-off and landing (eVTOL) aircraft, and autonomous air parcel delivery (AAPD) networks, requires advanced large-scale processing methods, such as ontological analytics. The integration of smart avionics includes the interaction between electronic equipment supporting Air Traffic Management (ATM), Unmanned Aerial Systems Traffic Management (UTM), and a Human–Machine Interface (HMI). Demonstrates the usability of the Avionics Analytics Ontology (AAO) to support the growing data space for urban air mobility challenges of UAVs, eVTOLs, and AAPDs. An avionics DSS, incorporating ontologies, mitigates unprecedented ATM challenges such as progressively sophisticated systems, densely occupied airspaces, and inexorably adverse weather conditions that overwhelm aircraft pilots, air traffic controllers, and air transport businesses, which prioritize safety and security in aviation procedures while sharing the airspace with pervasive Unmanned Aerial Vehicles (UAVs). The final section provides the conclusions and future research direction
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
