Abstract
The airworthiness certification of aerospace cyber-physical systems traditionally relies on the probabilistic safety assessment as a standard engineering methodology to quantify the potential risks associated with faults in system components. This paper presents and discusses the probabilistic safety assessment of detect and avoid (DAA) systems relying on multiple cooperative and non-cooperative tracking technologies to identify the risk of collision of unmanned aircraft systems (UAS) with other flight vehicles. In particular, fault tree analysis (FTA) is utilized to measure the overall system unavailability for each basic component failure. Considering the inter-dependencies of navigation and surveillance systems, the common cause failure (CCF)-beta model is applied to calculate the system risk associated with common failures. Additionally, an importance analysis is conducted to quantify the safety measures and identify the most significant component failures. Results indicate that the failure in traffic detection by cooperative surveillance systems contribute more to the overall DAA system functionality and that the probability of failure for ownship locatability in cooperative surveillance is greater than its traffic detection function. Although all the sensors individually yield 99.9% operational availability, the implementation of adequate multi-sensor DAA system relying on both cooperative and non-cooperative technologies is shown to be necessary to achieve the desired levels of safety in all possible encounters. These results strongly support the adoption of a unified analytical framework for cooperative/non-cooperative UAS DAA and elicits an evolution of the current certification framework to properly account for artificial intelligence and machine-learning based systems.
Highlights
While a steady growth of manned aviation has driven the advancement of communication, navigation and sensing (CNS) technologies to support a denser airspace exploitation, various technological and regulatory challenges have affected the development of autonomous separation assurance and collision avoidance (SA&CA) capabilities for unmanned aircraft systems (UAS)
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The reliability of UAS detect and avoid (DAA) systems based on automatic dependent surveillance-broadcast (ADS-B) and other cooperative/non-cooperative sensors was analyzed in this paper
Summary
While a steady growth of manned aviation has driven the advancement of communication, navigation and sensing (CNS) technologies to support a denser airspace exploitation, various technological and regulatory challenges have affected the development of autonomous separation assurance and collision avoidance (SA&CA) capabilities for unmanned aircraft systems (UAS). The provision of certified autonomous DAA capabilities is an indispensable milestone for the certification of UAS for safe non-segregated and beyond line of sight (BLOS) operations This is a widely recognized issue in the aerospace research community but to date, despite the extensive efforts, the various proposed DAA approaches have not satisfactorily addressed the overall safety risks. A comprehensive safety assessment is conducted considering the sensitivities, failures and degraded operations of systems and components of the overall DAA architecture Both qualitative and quantitative analysis are performed to identify and derive the risks of different component failure in both airborne and ground control platform using probabilistic safety assessment. A case study of ADS-B in as section a cooperative surveillance methodology
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