Autonomous Emergency Gliding Landing Guidance and Control of Tilt-Wing Electric Vertical Take-Off and Landing for Urban Air Mobility Missions Using Control Barrier Functions

Autonomous Emergency Gliding Landing Guidance and Control of Tilt-Wing Electric Vertical Take-Off and Landing for Urban Air Mobility Missions Using Control Barrier Functions

Urban Air Mobility (UAM) aims to transform urban transportation through innovative applications of electric Vertical Take-Off and Landing (eVTOL) aircraft. This paper focuses on tilt-wing eVTOLs, which offer significant advantages in energy efficiency and operational versatility. However, their uniq...

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Main Authors: Liqun Ma, Yangchen Ding, Jianzhong Yang
Format: Article
Language:English
Published: MDPI AG 2025-01-01
Series:Aerospace
Subjects:
emergency gliding landing guidance and control
tilt-wing eVTOL
UAM missions
control barrier functions
Online Access:https://www.mdpi.com/2226-4310/12/1/63
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author Liqun Ma
Yangchen Ding
Jianzhong Yang
author_facet Liqun Ma
Yangchen Ding
Jianzhong Yang
author_sort Liqun Ma
collection DOAJ
description Urban Air Mobility (UAM) aims to transform urban transportation through innovative applications of electric Vertical Take-Off and Landing (eVTOL) aircraft. This paper focuses on tilt-wing eVTOLs, which offer significant advantages in energy efficiency and operational versatility. However, their unique flight characteristics present challenges, particularly during emergency landings. To address this, we propose a novel control framework that utilizes control barrier functions (CBFs) to ensure safe landings within urban environments, characterized by numerous obstacles and varying conditions. By integrating trajectory generation, tracking, and attitude control under stringent safety constraints, our method prioritizes occupant safety while complying with FAA airworthiness standards. We illustrate the framework’s effectiveness through simulations, demonstrating its ability to guide eVTOLs to safe touchdowns despite power loss or other emergencies. This study not only advances the understanding of emergency landing mechanisms for eVTOLs but also contributes to the broader field of urban air traffic management, offering a foundation for future research and practical implementations of UAM. The innovative combination of CBFs and global optimization techniques sets a new precedent for resilient aircraft control in complex urban scenarios, paving the way for the safe integration of eVTOLs into everyday urban life.
format Article
id doaj-art-59f6eb3334764be2af31ebb11731ce3a
institution Kabale University
issn 2226-4310
language English
publishDate 2025-01-01
publisher MDPI AG
record_format Article
series Aerospace
spelling doaj-art-59f6eb3334764be2af31ebb11731ce3a2025-01-24T13:15:41ZengMDPI AGAerospace2226-43102025-01-011216310.3390/aerospace12010063Autonomous Emergency Gliding Landing Guidance and Control of Tilt-Wing Electric Vertical Take-Off and Landing for Urban Air Mobility Missions Using Control Barrier FunctionsLiqun Ma0Yangchen Ding1Jianzhong Yang2College of Safety Science and Engineering, Civil Aviation University of China, Tianjin 300300, ChinaCollege of Safety Science and Engineering, Civil Aviation University of China, Tianjin 300300, ChinaCollege of Safety Science and Engineering, Civil Aviation University of China, Tianjin 300300, ChinaUrban Air Mobility (UAM) aims to transform urban transportation through innovative applications of electric Vertical Take-Off and Landing (eVTOL) aircraft. This paper focuses on tilt-wing eVTOLs, which offer significant advantages in energy efficiency and operational versatility. However, their unique flight characteristics present challenges, particularly during emergency landings. To address this, we propose a novel control framework that utilizes control barrier functions (CBFs) to ensure safe landings within urban environments, characterized by numerous obstacles and varying conditions. By integrating trajectory generation, tracking, and attitude control under stringent safety constraints, our method prioritizes occupant safety while complying with FAA airworthiness standards. We illustrate the framework’s effectiveness through simulations, demonstrating its ability to guide eVTOLs to safe touchdowns despite power loss or other emergencies. This study not only advances the understanding of emergency landing mechanisms for eVTOLs but also contributes to the broader field of urban air traffic management, offering a foundation for future research and practical implementations of UAM. The innovative combination of CBFs and global optimization techniques sets a new precedent for resilient aircraft control in complex urban scenarios, paving the way for the safe integration of eVTOLs into everyday urban life.https://www.mdpi.com/2226-4310/12/1/63emergency gliding landing guidance and controltilt-wing eVTOLUAM missionscontrol barrier functions
spellingShingle Liqun Ma
Yangchen Ding
Jianzhong Yang
Autonomous Emergency Gliding Landing Guidance and Control of Tilt-Wing Electric Vertical Take-Off and Landing for Urban Air Mobility Missions Using Control Barrier Functions
Aerospace
emergency gliding landing guidance and control
tilt-wing eVTOL
UAM missions
control barrier functions
title Autonomous Emergency Gliding Landing Guidance and Control of Tilt-Wing Electric Vertical Take-Off and Landing for Urban Air Mobility Missions Using Control Barrier Functions
title_full Autonomous Emergency Gliding Landing Guidance and Control of Tilt-Wing Electric Vertical Take-Off and Landing for Urban Air Mobility Missions Using Control Barrier Functions
title_fullStr Autonomous Emergency Gliding Landing Guidance and Control of Tilt-Wing Electric Vertical Take-Off and Landing for Urban Air Mobility Missions Using Control Barrier Functions
title_full_unstemmed Autonomous Emergency Gliding Landing Guidance and Control of Tilt-Wing Electric Vertical Take-Off and Landing for Urban Air Mobility Missions Using Control Barrier Functions
title_short Autonomous Emergency Gliding Landing Guidance and Control of Tilt-Wing Electric Vertical Take-Off and Landing for Urban Air Mobility Missions Using Control Barrier Functions
title_sort autonomous emergency gliding landing guidance and control of tilt wing electric vertical take off and landing for urban air mobility missions using control barrier functions
topic emergency gliding landing guidance and control
tilt-wing eVTOL
UAM missions
control barrier functions
url https://www.mdpi.com/2226-4310/12/1/63
work_keys_str_mv AT liqunma autonomousemergencyglidinglandingguidanceandcontroloftiltwingelectricverticaltakeoffandlandingforurbanairmobilitymissionsusingcontrolbarrierfunctions
AT yangchending autonomousemergencyglidinglandingguidanceandcontroloftiltwingelectricverticaltakeoffandlandingforurbanairmobilitymissionsusingcontrolbarrierfunctions
AT jianzhongyang autonomousemergencyglidinglandingguidanceandcontroloftiltwingelectricverticaltakeoffandlandingforurbanairmobilitymissionsusingcontrolbarrierfunctions

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