The Optimal Size of a Heterogeneous Air Taxi Fleet in Advanced Air Mobility: A Traffic Demand and Flight Scheduling Approach-Reference-Cited by-同舟云学术

The Optimal Size of a Heterogeneous Air Taxi Fleet in Advanced Air Mobility: A Traffic Demand and Flight Scheduling Approach

Published:2024-02-11 Issue:1 Volume:4 Page:174-214
ISSN:2673-7590
Container-title:Future Transportation
language:en
Short-container-title:Future Transportation

Author:

Lindner Martin¹^ORCID,Brühl Robert¹,Berger Marco¹,Fricke Hartmut¹^ORCID

Affiliation:

1. Institute of Logistics and Aviation, Technical University of Dresden, Hettnerstr. 1-3, 01069 Dresden, Germany

Abstract

Introducing Advanced Air Mobility (AAM) as a novel transportation mode poses unique challenges due to limited practical and empirical data. One of these challenges involves accurately estimating future passenger demand and the required number of air taxis, given uncertainties in modal shift dynamics, induced traffic patterns, and long-term price elasticity. In our study, we use mobility data obtained from a Dresden traffic survey and modal shift rates to estimate the demand for AAM air taxi operations for this regional use case. We organize these operations into an air taxi rotation schedule using a Mixed Integer Linear Programming (MILP) optimization model and set a tolerance for slight deviations from the requested arrival times for higher productivity. The resulting schedule aids in determining the AAM fleet size while accounting for flight performance, energy consumption, and battery charging requirements tailored to three distinct types of air taxi fleets. According to our case study, the methodology produces feasible and high-quality air taxi flight rotations within an efficient computational time of 1.5 h. The approach provides extensive insights into air taxi utilization, charging durations at various locations, and assists in fleet planning that adapts to varying, potentially uncertain, traffic demands. Our findings reveal an average productivity of 12 trips per day per air taxi, covering distances from 13 to 99 km. These outcomes contribute to a sustainable, business-focused implementation of AAM while highlighting the interaction between operational parameters and overall system performance and contributing to vertiport capacity considerations.

Funder

Saxon State Ministry for Regional Development

German Federal Ministry for Digital and Transport

Publisher

MDPI AG

Link

https://www.mdpi.com/2673-7590/4/1/10/pdf

Reference92 articles.

1. UAM Initiative Cities Community (UIC2) (2023, July 25). Manifesto on the Multilevel Governance of the Urban Sky. Available online: https://civitas.eu/sites/default/files/UIC2%20Manifesto%20-%20Multilevel%20Governance%20of%20the%20Urban%20Sky_wtih%20supporting%20cities_15Sep2022.pdf.

2. European Commission (EC) (2024, January 10). Smart Cities. Available online: https://commission.europa.eu/eu-regional-and-urban-development/topics/cities-and-urban-development/city-initiatives/smart-cities_en.

3. Agouridas, V., Biermann, F., Czaya, A., Richter, D., Stemmler, J., Stęchły, J., Witkowska-Konieczny, A., Metropolia, G., Kumar, R., and Metropole, T. (2024, January 10). Urban Air Mobility and Sustainable Urban Mobility Planning—Practioner Briefing. 12 2021. Available online: https://doi.org/10.6084/m9.figshare.19314005.v1.

4. Fraske, T. (2024, January 11). Change Agency and Path Creation toward Future Transport Systems: A Case Study of the Emerging Urban Air Mobility in Germany. Available online: http://dx.doi.org/10.13140/RG.2.2.27722.24000.

5. Brühl, R., Fricke, H., Tober, L.A., Dexl, F., Markmiller, J., Walla, N., Mutz, C., Erfurt, R., Fraske, T., and Medeiros, R.M. (2024, January 11). SmartFly—Concept for the Intelligent Integration and Economic Use of Air Taxis in Saxony. Available online: https://doi.org/10.13140/RG.2.2.24570.98245.