A. Morfin Veytia
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13 records found
1
Constrained Urban Airspace Design
Exploring future rules, strategies, and risk
Operating in an urban environment poses challenges to air vehicles that are distinct from traditional air traffic management. Mainly, drones will need to avoid both dynamic (other drones) and static (buildings and city infrastructure) obstacles during flight. Additionally, the expected densities will be orders of magnitude larger than what is currently seen in conventional airspace.
However, this thesis limits the analysis to constrained airspace, where drones operate in urban areas between tall buildings and/or other infrastructure. This means that drones are restricted to fly along a constrained network that is above the existing street network or any other pre-defined network with a fixed route topology. In constrained airspace, drones can no longer fly directly to their destination and have points of convergence at the intersections of the network.
This thesis focuses on addressing challenges and risks of high-density air operations in constrained urban environments via two research goals. Thesis goal 1 analyses how airspace designs and rules affect the safety and efficiency of the urban airspace at varying traffic density. Thesis goal 2 develops and evaluates a method for analysing the operational feasibility of urban air missions considering local wind conditions.
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Operating in an urban environment poses challenges to air vehicles that are distinct from traditional air traffic management. Mainly, drones will need to avoid both dynamic (other drones) and static (buildings and city infrastructure) obstacles during flight. Additionally, the expected densities will be orders of magnitude larger than what is currently seen in conventional airspace.
However, this thesis limits the analysis to constrained airspace, where drones operate in urban areas between tall buildings and/or other infrastructure. This means that drones are restricted to fly along a constrained network that is above the existing street network or any other pre-defined network with a fixed route topology. In constrained airspace, drones can no longer fly directly to their destination and have points of convergence at the intersections of the network.
This thesis focuses on addressing challenges and risks of high-density air operations in constrained urban environments via two research goals. Thesis goal 1 analyses how airspace designs and rules affect the safety and efficiency of the urban airspace at varying traffic density. Thesis goal 2 develops and evaluates a method for analysing the operational feasibility of urban air missions considering local wind conditions.
Decentralised Traffic Management for Constrained Urban Airspace
Dynamically Generating and Acting Upon Aggregate Flow Data
Dynamic Capacity Balancing in Urban Airspace
Comparing Historical and Real-time Aggregate Flow Data
As urban ground transportation congestion increases, there is growing interest in urban air transportation, such as delivery drones and air taxis. However, managing air traffic in densely populated urban areas poses significant challenges, which require effective flight planning, separation management, and airspace design. This paper investigates dynamic capacity balancing methods to manage air traffic in constrained urban airspace, where drones must fly above the existing road network. Specifically, it compares the effectiveness of labelling high-complexity zones using historical data versus real-time aggregate flow data. The results indicate that while both approaches reduce airspace intrusions and improve safety, the best approach depends on traffic demand levels. At lower demand levels, using historical data yields better safety outcomes, whereas using real-time data is more effective at higher demand levels due to its flexibility. At their best, both methods increase the travel distance by less than 6% while reducing airspace intrusions by 30% compared to a case without dynamic capacity balancing.
Unmanned Aircraft Systems (UAS) Traffic Management (UTM) is an active research subject as its proposed applications are increasing. UTM aims to enable a variety of UAS operations, including package delivery, infrastructure inspection, and emergency missions. That creates the need for extensive research on how to incorporate such traffic, as conventional methods and operations used in Air Traffic Management (ATM) are not suitable for constrained urban airspace. This paper proposes and compares several traffic capacity balancing methods developed for a UTM system designed to be used in highly dense, very low-level urban airspace. Three types of location-based dynamic traffic capacity management techniques are tested: street-based, grid-based, and cluster-based. The proposed systems are tested by simulating traffic within mixed (constrained and open) urban airspace based on the city of Vienna at five different traffic densities. Results show that using local, area-based clustering for capacity balancing within a UTM system improves safety, efficiency, and capacity metrics, especially when simulated or historical traffic data are used.
Metropolis II
Investigating the Future Shape of Air Traffic Control in Highly Dense Urban Airspace
Metropolis II aims to provide insights in what is needed to enable high-density urban air operations. It does this by investigating the foundation for U-space U3/U4 services. The final goal is to provide a unified approach for strategic deconfliction, tactical deconfliction, and dynamic capacity management. Highly-dense operations in constrained urban airspace will likely require a degree of complexity that does not exist in modern-day air traffic management. The expected high traffic demand will require a shared use of the airspace instead of assigning exclusive use of blocks of the airspace to some flights. A unified approach for traffic management is needed because at high-densities, airspace design, flight planning, and separation management become increasingly interdependent. Metropolis II builds upon the results of the first Metropolis project. Three concepts with a varying degree of centralisation will be compared using simulations. (1) The centralised concept will take a global approach for separation management. (2) The decentralised concept aims to give the individual agents separation responsibility. (3) The hybrid concept tries to combine a centralised strategic planning agent with a robust tactical separation strategy.
Metropolis II
Benefits of Centralised Separation Management in High-Density Urban Airspace