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NASA NTRS · Conference Paper

An Experimental System for Strategic Flight Path Management in Advanced Air Mobility

Published 2024-01-19 From Langley Research Center 4 authors

Attribution

This is the abstract and citation. Full text lives at NASA NTRS — we link out rather than host. All credit to the authors and Langley Research Center.

Abstract

Verbatim from NASA NTRS. Not paraphrased, not summarized.

In the concept envisioned for Urban Air Mobility (UAM) operations, fleets of electric vertical takeoff and landing (eVTOL) vehicles would operate between vertiports distributed within a densely populated area. These operations would be largely independent from the existing air traffic control system and would place the responsibility for flight planning and aircraft separation on fleet operators. The fourth major level on the UAM Maturity Level scale, UML-4, relies on “collaborative and responsible” automation to enable operations in non-visual conditions with medium traffic density (hundreds of aircraft in one metropolitan region) and medium complexity. This level of service places many requirements on automation systems to assist the operators of these aircraft. NASA has developed the Autonomous Operations Planner (AOP), a reference prototype Flight Path Management automation system, and has modified AOP to support research of anticipated UML-4 operations. AOP creates a four-dimensional flight plan conforming to the constraints of these operations, evaluates and modifies the flight plan during flight as conditions and constraints evolve, and coordinates the flight plan with other airspace users and with service providers. This version of AOP has been integrated into the Sikorsky Autonomy Research Aircraft and used in a flight test activity. In this paper we discuss anticipated characteristics of UAM operations, modifications that were made to AOP to adapt to that environment or to support the flight test, and observations of software and aircraft performance during the flight test. The aircraft achieved four-dimensional conformance with the flight plan and AOP provided adequate planning in almost all cases. We discuss improvements that could be made to AOP to address deficiencies that were observed.

Authors

  • David A. Karr Analytical Mechanics Associates (United States)
  • James L. Sturdy Analytical Mechanics Associates (United States)
  • Bryan A. Barrows Langley Research Center
  • Mark G. Ballin Langley Research Center

Keywords

  • Autonomous Operations Planner
  • AOP
  • Advanced Air Mobility
  • AAM
  • Urban Air Mobility
  • UAM
  • Flight Path Management
  • FPM
  • Dynamic Path Planning
  • DPP

Citation: David A. Karr, James L. Sturdy, Bryan A. Barrows , et al. (2024). An Experimental System for Strategic Flight Path Management in Advanced Air Mobility. Langley Research Center. NASA NTRS ID 20230017086. https://ntrs.nasa.gov/citations/20230017086 ↗