A Layered Structure Approach to Assure Urban Air Mobility Safety and Efficiency-Reference-Cited by-同舟云学术

A Layered Structure Approach to Assure Urban Air Mobility Safety and Efficiency

Published:2023-06-30 Issue:7 Volume:10 Page:609
ISSN:2226-4310
Container-title:Aerospace
language:en
Short-container-title:Aerospace

Author:

Gordo Victor¹²^ORCID,Becerra Ines¹,Fransoy Alejandro³,Ventas Enrique⁴,Menendez-Ponte Pablo⁵,Xu Yan⁶,Tojal Marta⁷,Perez-Castan Javier²^ORCID,Perez Sanz Luis²^ORCID

Affiliation:

1. Ingeniería y Economía del Transporte (INECO), 28036 Madrid, Spain

2. Sistemas Aeroespaciales, Transporte Aéreo y Aeropuertos, Universidad Politécnica de Madrid (UPM)–ETSI Aeronáutica y del Espacio, 28040 Madrid, Spain

3. Boeing Researh and Technology Europe (BRTE), 28042 Madrid, Spain

4. Galicia Institute of Technology (ITG), 15003 A Coruña, Spain

5. NTT Data, 28050 Madrid, Spain

6. School of Aerospace, Transport and Manufacturing, Cranfield University, Cranfield MK43 0AL, UK

7. Royal Netherlands Aerospace Centre (NLR), 1059 CM Amsterdam, The Netherlands

Abstract

The demand for air mobility services will depend on the safety of these operations but also on the transportation time savings in congested urban areas. An adequate air space structure is therefore essential to achieve both objectives. Corridors, the most extended solution proposed nowadays, can meet the safety requirements necessary for air taxi operations, but they are rigid (point-to-point solutions) and would increase delays. As an alternative, this paper presents the airspace structure proposed in the SESAR AMU-LED Project, based on layers to assure both safety and efficiency of air taxi operations. In this proposal, small UAS will fly in the bottom part, called the Very Low Level, whereas air taxis will fly in the upper part. The paper applies a collision risk model to determine the minimum required safety buffer between both layers to assure the necessary safety levels. The results obtained show that a buffer of 10 m between them would meet the required safety levels for air taxi operations.

Funder

SESAR Joint Undertaking

Publisher

MDPI AG

Subject

Aerospace Engineering

Link

https://www.mdpi.com/2226-4310/10/7/609/pdf

Reference55 articles.

1. Antoniou, C., Efthymiou, D., and Chaniotakis, E. (2020). Demand for Emerging Transportation Systems, Elsevier. [1st ed.].

2. Urban air mobility and flying cars: Overview, examples, prospects, drawbacks, and solutions;Marzouk;Open Eng.,2022

3. Reich, C., Goyal, R., Cohen, A., Serrao, J., Kimmel, S., Fernando, C., and Shaheen, S. (2023, January 22). Urban Air Mobility Market Study, Available online: https://ntrs.nasa.gov/citations/20190001472.

4. Grandl, G., Ostgathe, M., Cachay, J., Doppler, S., Salib, J., and Ross, H. (2018). The Future of Vertical Mobility: Sizing the Market for Passenger, Inspection, and Goods Services Until 2035, Porsche Consulting. Available online: https://www.porsche-consulting.com/fileadmin/docs/04_Medien/Publikationen/TT1371_The_Future_of_Vertical_Mobility/The_Future_of_Vertical_Mobility_A_Porsche_Consulting_study__C_2018.pdf.

5. Roland Berger (2023, January 22). Urban Air Mobility: The Rise of a New Mode of Transportation. Available online: https://www.rolandberger.com/en/Insights/Publications/Passenger-drones-ready-for-take-off.html.

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