The main problem to be addressed in this project is to solve the growing demand for drones in densely populated areas, without compromising safety while taking into consideration turbulent wind shear.
USEPE contributes to the advance of U-space services to enable the safe and efficient operations of a large number of drones, without adversely affecting manned aviation by ensuring safe separation management of drones through the relevant flight planning management and de-confliction.
The goal of USEPE is to propose, develop and evaluate a Concept of Operations and a set of enabling technologies aimed at ensuring the safe separation of drones (from each other and from manned aviation) in the U-space environment, with particular focus on densely populated areas.
In order to achieve this goal, four specific objectives have been identified:
• Identify who shall be the predetermined separator (the drones themselves or the U-space systems) throughout the strategic and tactical planning phases.
• Define and simulate a set of concepts to provide safe separation for different kind of drones in each planning phase.
• Assess the impact of the proposed concepts on different Key Performance Areas (KPAs), in particular on Safety, Capacity and Efficiency, in order to derive conclusions and recommendations on the most adequate approach for each operational environment.
• Disseminate the project results to all concerned Stakeholders in order to collect their feedback regarding the appropriateness of the transition to the subsequent stages of the R&I cycle.
As a conclusion of the Action, USEPE solution can be summarise as follows:
USEPE-SOL consists of a new separation method for drones in the urban environment, the Dynamic Density Corridor Concept (D2-C2), aiming at ensuring the safe separation of drones (from each other and from manned aviation) in the U-space environment, with particular focus on densely populated areas. The method relies on three pillars:
• Segments are 3D volumes, each one with its own parameters: speed limit, capacity, performance requirements, etc., which are common for every drone flight in a particular segment. Segmentation of the airspace is a dynamic, fast and flexible process.
• High-speed corridors are defined as three-dimensional tubes in space where the drones travel along them in one direction only
• Geovectoring rules are defined for flying both in corridors and segments (minimum and maximum speed, rate of ascent/descent and limits to heading), to manage traffic complexity by reducing the relative velocity between drones, lowering collision risks.