Multiple Cooperative UAS Mid-Air Collision Probability Assessment and Monte-Carlo Validation in Urban Air Mobility

Jinpeng Zhang; Yan Xu; Jinjiang Yu; Kaiquan Cai; Gokhan Inalhan

doi:10.1109/ICNS65417.2025.10976756

Multiple Cooperative UAS Mid-Air Collision Probability Assessment and Monte-Carlo Validation in Urban Air Mobility

Jinpeng Zhang, Yan Xu, Jinjiang Yu, Kaiquan Cai, Gokhan Inalhan

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Risk assessment is pivotal for enabling unmanned aircraft systems (UAS) in urban airspace, particularly under high-density, cooperative flight operations. This paper presents a systematic approach to quantifying the mid-air collision (MAC) risk for cooperative UAS in urban air mobility (UAM) by incorporating flight characteristics, operational uncertainties, and latency effects. We propose a novel MAC evolution timeline comprising three safety barriers (strategic, tactical, and conflict avoidance mitigation) designed to prevent conflicts from culminating in a collision. Guided by this timeline, the failure of strategic mitigation is captured through a conflict probability estimation model, which includes an analytical solution for rapidly identifying threats. The failure of tactical mitigation is then evaluated via an approach time estimation model that integrates multiple maneuver strategies to refine outcome predictions. Finally, conflict avoidance failure is characterized using the risk ratio associated with detection and avoidance (DAA) systems. By combining the failure probabilities of these three safety barriers, we derive the overall MAC probability. Monte Carlo simulations validate the proposed models, revealing that the resulting probability curves closely match the theoretical predictions.

Original language	English
Title of host publication	ICNS 2025 - Integrated Communications, Navigation and Surveillance Conference
Subtitle of host publication	Integrated CNS: Towards Innovative and Efficient CNS Service Provision
Publisher	Institute of Electrical and Electronics Engineers Inc.
ISBN (Electronic)	9798331534738
DOIs	https://doi.org/10.1109/ICNS65417.2025.10976756
Publication status	Published - 2025
Externally published	Yes
Event	2025 Integrated Communications, Navigation and Surveillance Conference, ICNS 2025 - Brussels, Belgium Duration: 8 Apr 2025 → 10 Apr 2025

Publication series

Name	Integrated Communications, Navigation and Surveillance Conference, ICNS
ISSN (Print)	2155-4943
ISSN (Electronic)	2155-4951

Conference

Conference	2025 Integrated Communications, Navigation and Surveillance Conference, ICNS 2025
Country/Territory	Belgium
City	Brussels
Period	8/04/25 → 10/04/25

Bibliographical note

Publisher Copyright:
© 2025 IEEE.

Keywords

Mid-Air Collision
Monte-Carlo simulation
Urban air mobility
cooperative unmanned aircraft systems
safety assessment

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1109/ICNS65417.2025.10976756

Cite this

Zhang, J., Xu, Y., Yu, J., Cai, K., & Inalhan, G. (2025). Multiple Cooperative UAS Mid-Air Collision Probability Assessment and Monte-Carlo Validation in Urban Air Mobility. In ICNS 2025 - Integrated Communications, Navigation and Surveillance Conference: Integrated CNS: Towards Innovative and Efficient CNS Service Provision (Integrated Communications, Navigation and Surveillance Conference, ICNS). Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/ICNS65417.2025.10976756

Zhang, Jinpeng ; Xu, Yan ; Yu, Jinjiang et al. / Multiple Cooperative UAS Mid-Air Collision Probability Assessment and Monte-Carlo Validation in Urban Air Mobility. ICNS 2025 - Integrated Communications, Navigation and Surveillance Conference: Integrated CNS: Towards Innovative and Efficient CNS Service Provision. Institute of Electrical and Electronics Engineers Inc., 2025. (Integrated Communications, Navigation and Surveillance Conference, ICNS).

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title = "Multiple Cooperative UAS Mid-Air Collision Probability Assessment and Monte-Carlo Validation in Urban Air Mobility",

abstract = "Risk assessment is pivotal for enabling unmanned aircraft systems (UAS) in urban airspace, particularly under high-density, cooperative flight operations. This paper presents a systematic approach to quantifying the mid-air collision (MAC) risk for cooperative UAS in urban air mobility (UAM) by incorporating flight characteristics, operational uncertainties, and latency effects. We propose a novel MAC evolution timeline comprising three safety barriers (strategic, tactical, and conflict avoidance mitigation) designed to prevent conflicts from culminating in a collision. Guided by this timeline, the failure of strategic mitigation is captured through a conflict probability estimation model, which includes an analytical solution for rapidly identifying threats. The failure of tactical mitigation is then evaluated via an approach time estimation model that integrates multiple maneuver strategies to refine outcome predictions. Finally, conflict avoidance failure is characterized using the risk ratio associated with detection and avoidance (DAA) systems. By combining the failure probabilities of these three safety barriers, we derive the overall MAC probability. Monte Carlo simulations validate the proposed models, revealing that the resulting probability curves closely match the theoretical predictions.",

keywords = "Mid-Air Collision, Monte-Carlo simulation, Urban air mobility, cooperative unmanned aircraft systems, safety assessment",

author = "Jinpeng Zhang and Yan Xu and Jinjiang Yu and Kaiquan Cai and Gokhan Inalhan",

note = "Publisher Copyright: {\textcopyright} 2025 IEEE.; 2025 Integrated Communications, Navigation and Surveillance Conference, ICNS 2025 ; Conference date: 08-04-2025 Through 10-04-2025",

year = "2025",

doi = "10.1109/ICNS65417.2025.10976756",

language = "English",

series = "Integrated Communications, Navigation and Surveillance Conference, ICNS",

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Zhang, J, Xu, Y, Yu, J, Cai, K & Inalhan, G 2025, Multiple Cooperative UAS Mid-Air Collision Probability Assessment and Monte-Carlo Validation in Urban Air Mobility. in ICNS 2025 - Integrated Communications, Navigation and Surveillance Conference: Integrated CNS: Towards Innovative and Efficient CNS Service Provision. Integrated Communications, Navigation and Surveillance Conference, ICNS, Institute of Electrical and Electronics Engineers Inc., 2025 Integrated Communications, Navigation and Surveillance Conference, ICNS 2025, Brussels, Belgium, 8/04/25. https://doi.org/10.1109/ICNS65417.2025.10976756

Multiple Cooperative UAS Mid-Air Collision Probability Assessment and Monte-Carlo Validation in Urban Air Mobility. / Zhang, Jinpeng; Xu, Yan; Yu, Jinjiang et al.
ICNS 2025 - Integrated Communications, Navigation and Surveillance Conference: Integrated CNS: Towards Innovative and Efficient CNS Service Provision. Institute of Electrical and Electronics Engineers Inc., 2025. (Integrated Communications, Navigation and Surveillance Conference, ICNS).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Zhang, Jinpeng

AU - Xu, Yan

AU - Yu, Jinjiang

AU - Cai, Kaiquan

AU - Inalhan, Gokhan

PY - 2025

Y1 - 2025

N2 - Risk assessment is pivotal for enabling unmanned aircraft systems (UAS) in urban airspace, particularly under high-density, cooperative flight operations. This paper presents a systematic approach to quantifying the mid-air collision (MAC) risk for cooperative UAS in urban air mobility (UAM) by incorporating flight characteristics, operational uncertainties, and latency effects. We propose a novel MAC evolution timeline comprising three safety barriers (strategic, tactical, and conflict avoidance mitigation) designed to prevent conflicts from culminating in a collision. Guided by this timeline, the failure of strategic mitigation is captured through a conflict probability estimation model, which includes an analytical solution for rapidly identifying threats. The failure of tactical mitigation is then evaluated via an approach time estimation model that integrates multiple maneuver strategies to refine outcome predictions. Finally, conflict avoidance failure is characterized using the risk ratio associated with detection and avoidance (DAA) systems. By combining the failure probabilities of these three safety barriers, we derive the overall MAC probability. Monte Carlo simulations validate the proposed models, revealing that the resulting probability curves closely match the theoretical predictions.

AB - Risk assessment is pivotal for enabling unmanned aircraft systems (UAS) in urban airspace, particularly under high-density, cooperative flight operations. This paper presents a systematic approach to quantifying the mid-air collision (MAC) risk for cooperative UAS in urban air mobility (UAM) by incorporating flight characteristics, operational uncertainties, and latency effects. We propose a novel MAC evolution timeline comprising three safety barriers (strategic, tactical, and conflict avoidance mitigation) designed to prevent conflicts from culminating in a collision. Guided by this timeline, the failure of strategic mitigation is captured through a conflict probability estimation model, which includes an analytical solution for rapidly identifying threats. The failure of tactical mitigation is then evaluated via an approach time estimation model that integrates multiple maneuver strategies to refine outcome predictions. Finally, conflict avoidance failure is characterized using the risk ratio associated with detection and avoidance (DAA) systems. By combining the failure probabilities of these three safety barriers, we derive the overall MAC probability. Monte Carlo simulations validate the proposed models, revealing that the resulting probability curves closely match the theoretical predictions.

KW - Mid-Air Collision

KW - Monte-Carlo simulation

KW - Urban air mobility

KW - cooperative unmanned aircraft systems

KW - safety assessment

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M3 - Conference contribution

AN - SCOPUS:105005208678

T3 - Integrated Communications, Navigation and Surveillance Conference, ICNS

BT - ICNS 2025 - Integrated Communications, Navigation and Surveillance Conference

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - 2025 Integrated Communications, Navigation and Surveillance Conference, ICNS 2025

Y2 - 8 April 2025 through 10 April 2025

ER -

Zhang J, Xu Y, Yu J, Cai K, Inalhan G. Multiple Cooperative UAS Mid-Air Collision Probability Assessment and Monte-Carlo Validation in Urban Air Mobility. In ICNS 2025 - Integrated Communications, Navigation and Surveillance Conference: Integrated CNS: Towards Innovative and Efficient CNS Service Provision. Institute of Electrical and Electronics Engineers Inc. 2025. (Integrated Communications, Navigation and Surveillance Conference, ICNS). doi: 10.1109/ICNS65417.2025.10976756

Multiple Cooperative UAS Mid-Air Collision Probability Assessment and Monte-Carlo Validation in Urban Air Mobility

Abstract

Publication series

Conference

Bibliographical note

Keywords

UN SDGs

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