Urban Air Mobility Airspace Integration Concepts and Considerations

Thipphavong, David P.; Apaza, Rafael D.; Barmore, Bryan E.; Battiste, Vernol; Belcastro, Christine M.; Burian, Barbara K.; Dao, Quang; Feary, Michael; Go, Susie; Goodrich, Kenneth H.; Homola, Jeffrey; Idris, Husni; Kopardekar, Parimal; Lachter, Joel; Neogi, Natasha A.; Ng, Hokkwan; Oseguera-Lohr, Rosa M.; Patterson, Michael D.; Verma, Savita

doi:10.2514/6.2018-3676

Cited by 266 publications

(154 citation statements)

References 13 publications

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“…However, technologists are already developing concept models for future flying car models that will be remotely piloted and supervised either: (a) by live humans on the ground, or (b) by autonomous systems in the air and/or on the ground. To operate "urban air mobility (UAM)" vehicles (either with or without passengers) without a pilot would depend not only on the Certification of the vehicle, but likewise on the Certification of pilots and support systems on the ground-for which suitable policies have not yet been established (Thipphavong et al, 2018). Ultimately, advanced (virtual) M&S will be required to specify appropriate training systems (with suitable fidelity), and design standardized training scenarios for future flying car operators-particularly for handling complex ground-air and air-ground transitions.…”

Section: Pilot Training and Certification Standardsmentioning

confidence: 99%

The Flying Car—Challenges and Strategies Toward Future Adoption

Ahmed

Hulme²,

Fountas

et al. 2020

Front. Built Environ.

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In recent years, our surface transportation infrastructure is suffering from overuse, extreme traffic congestion, and roadway disrepair. Instead of following the traditional infrastructure expansion policy, current transportation research focuses on developing innovative and novel solutions to the aforementioned issues. Current pathways to overcoming these issues include the gradual transition toward a number of emerging transportation technologies, such as, autonomous motor vehicles for human transport, as well as unmanned aerial vehicles (UAV's) and "drone" technologies for surveillance, and package deliveries. However, as a long-term solution, transportation scientists are also investigating the once-seemingly futuristic notion of flying car technology-a convergent form of ground/air vehicle transportation, and assessing associated regulations. In this paper, an extensive review of current literature is conducted to explore the technological capabilities of flying cars-each requiring appropriate regulations and governance-to become fully sustainable. Specifically, issues pertinent to training, safety, environment, navigation, infrastructure, logistics/sustainability, and cybersecurity and human factors are explored. This paper concludes with a preliminary quantitative analysis exploring the public perceptions associated with flying cars-including anticipated benefits, concerns, and willingness to both hire and acquire the technology once available to consumers. Insights offered by this data will help inform next-generation policies and standards associated with the gradual advancement of flying cars.

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Section: Pilot Training and Certification Standardsmentioning

confidence: 99%

The Flying Car—Challenges and Strategies Toward Future Adoption

Ahmed

Hulme²,

Fountas

et al. 2020

Front. Built Environ.

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“…These two cases are also addressed in the verification studies presented in Section 4. For UAM traffic, it is recommended to adapt helicopter routes by bounded the trajectories as corridors [34]. However, simply adapting current helicopter routes will not respond to the current demands for Mobility-as-a-Service (MAAS).…”

Section: Urban Uam/uas Operational Conceptmentioning

confidence: 99%

A Performance-Based Airspace Model for Unmanned Aircraft Systems Traffic Management

et al. 2020

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Recent evolutions of the Unmanned Aircraft Systems (UAS) Traffic Management (UTM) concept are driving the introduction of new airspace structures and classifications, which must be suitable for low-altitude airspace and provide the required level of safety and flexibility, particularly in dense urban and suburban areas. Therefore, airspace classifications and structures need to evolve based on appropriate performance metrics, while new models and tools are needed to address UTM operational requirements, with an increasing focus on the coexistence of manned and unmanned Urban Air Mobility (UAM) vehicles and associated Communication, Navigation and Surveillance (CNS) infrastructure. This paper presents a novel airspace model for UTM adopting Performance-Based Operation (PBO) criteria, and specifically addressing urban airspace requirements. In particular, a novel airspace discretisation methodology is introduced, which allows dynamic management of airspace resources based on navigation and surveillance performance. Additionally, an airspace sectorisation methodology is developed balancing the trade-off between communication overhead and computational complexity of trajectory planning and re-planning. Two simulation case studies are conducted: over the skyline and below the skyline in Melbourne central business district, utilising Global Navigation Satellite Systems (GNSS) and Automatic Dependent Surveillance-Broadcast (ADS-B). The results confirm that the proposed airspace sectorisation methodology promotes operational safety and efficiency and enhances the UTM operators’ situational awareness under dense traffic conditions introducing a new effective 3D airspace visualisation scheme, which is suitable both for mission planning and pre-tactical UTM operations. Additionally, the proposed performance-based methodology can accommodate the diversity of infrastructure and vehicle performance requirements currently envisaged in the UTM context. This facilitates the adoption of this methodology for low-level airspace integration of UAS (which may differ significantly in terms of their avionics CNS capabilities) and set foundations for future work on tactical online UTM operations.

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“…• flight corridors are pre-defined in the UAM network to avoid collisions [35] • no hard limit is placed on how many aircraft can be placed in an air-holding pattern at the same time • the airspace of a vertiport has one approach fix and one departure fix • appropriate separation requirements are assumed to be met when an aircraft is using the defined approach and departure fixes 3) Rules of sequencing and spacing:…”

Section: A Simulation Modeling Assumptionsmentioning

confidence: 99%

Analysis of Fleet Management and Infrastructure Constraints in On-Demand Urban Air Mobility Operations

Sheng

Egorov

Kochenderfer

2020

Aiaa Aviation 2020 Forum

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A significant challenge in estimating operational feasibility of Urban Air Mobility (UAM) missions lies in understanding how choices in design impact the performance of a complex system-of-systems. This work examines the ability of the UAM ecosystem and the operations within it to meet a variety of demand profiles that may emerge in the coming years. We perform a set of simulation driven feasibility and scalability analyses based on UAM operational models with the goal of estimating capacity and throughput for a given set of parameters that represent an operational UAM ecosystem. UAM ecosystem design guidelines, vehicle constraints, and effective operational policies can be drawn from our analysis. Results show that, while critical for enabling UAM, the performance of the UAM ecosystem is robust to variations in ground infrastructure and fleet design decisions, while being sensitive to decisions for fleet and traffic management policies. We show that so long as the ecosystem design parameters for ground infrastructure and fleet design fall within a sensible range, the performance of the UAM ecosystem is affected by the policies used to manage the UAM traffic.

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Urban Air Mobility Airspace Integration Concepts and Considerations

Cited by 266 publications

References 13 publications

The Flying Car—Challenges and Strategies Toward Future Adoption

The Flying Car—Challenges and Strategies Toward Future Adoption

A Performance-Based Airspace Model for Unmanned Aircraft Systems Traffic Management

Analysis of Fleet Management and Infrastructure Constraints in On-Demand Urban Air Mobility Operations

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