Digital Twin-Enabled Obstacle Avoidance System for the MADNI Drone

Cara Rose; Robert McMurray; Muhammad Usman Hadi

doi:10.1109/icetecc65365.2025.11070262

Digital Twin-Enabled Obstacle Avoidance System for the MADNI Drone

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

Abstract

Obstacle avoidance is an essential ability for unmanned aerial vehicles (UAVs) operating in complex and dynamic environments. This work uses the Manoeuvrable Autonomous Drone for Navigation and Intelligence (MADNI) and integrates the 3D Vector Field Histogram Plus (3D VFH+) algorithm with Light Detection and Ranging (LiDAR) sensors to enhance real-time obstacle avoidance implemented on a digital twin of a real life UAV system. The 3D VFH+ algorithm enables MADNI to calculate optimal azimuth and pitch angles for safe navigation through obstacle-dense environments. LiDAR sensors provide high-precision, real-time spatial data, generating detailed three-dimensional environmental maps essential for detecting and avoiding obstacles. Integrating the 3D VFH+ algorithm with the LiDAR system allows MADNI to autonomously navigate through challenging environments with varying obstacle densities and configurations. The proposed system demonstrates its versatility in applications such as search and rescue (SAR) missions, surveillance, and environmental monitoring, enhancing safety, efficiency, and operational autonomy for UAV platforms.

Original language	English
Title of host publication	2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC)
Publisher	IEEE
Pages	1-6
Number of pages	6
ISBN (Electronic)	979-8-3315-4338-9
ISBN (Print)	979-8-3315-4338-9, 979-8-3315-4339-6
DOIs	https://doi.org/10.1109/icetecc65365.2025.11070262
Publication status	Published online - 14 Jul 2025
Event	2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC) - Jamshoro, Pakistan Duration: 23 Apr 2025 → 25 Apr 2025

Publication series

Name	2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC)
Publisher	IEEE Control Society

Conference

Conference	2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC)
Country/Territory	Pakistan
City	Jamshoro
Period	23/04/25 → 25/04/25

Bibliographical note

Publisher Copyright:
© 2025 IEEE.

Keywords

UAV
obstacle avoidance
PID
PSO
GA
3D VFH+
MADNI
Obstacle avoidance

Access to Document

10.1109/icetecc65365.2025.11070262

Cite this

Rose, C., McMurray, R., & Hadi, M. U. (2025). Digital Twin-Enabled Obstacle Avoidance System for the MADNI Drone. In 2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC) (pp. 1-6). (2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC)). IEEE. Advance online publication. https://doi.org/10.1109/icetecc65365.2025.11070262

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title = "Digital Twin-Enabled Obstacle Avoidance System for the MADNI Drone",

abstract = "Obstacle avoidance is an essential ability for unmanned aerial vehicles (UAVs) operating in complex and dynamic environments. This work uses the Manoeuvrable Autonomous Drone for Navigation and Intelligence (MADNI) and integrates the 3D Vector Field Histogram Plus (3D VFH+) algorithm with Light Detection and Ranging (LiDAR) sensors to enhance real-time obstacle avoidance implemented on a digital twin of a real life UAV system. The 3D VFH+ algorithm enables MADNI to calculate optimal azimuth and pitch angles for safe navigation through obstacle-dense environments. LiDAR sensors provide high-precision, real-time spatial data, generating detailed three-dimensional environmental maps essential for detecting and avoiding obstacles. Integrating the 3D VFH+ algorithm with the LiDAR system allows MADNI to autonomously navigate through challenging environments with varying obstacle densities and configurations. The proposed system demonstrates its versatility in applications such as search and rescue (SAR) missions, surveillance, and environmental monitoring, enhancing safety, efficiency, and operational autonomy for UAV platforms.",

keywords = "UAV, obstacle avoidance, PID, PSO, GA, 3D VFH+, MADNI, Obstacle avoidance",

author = "Cara Rose and Robert McMurray and Hadi, \{Muhammad Usman\}",

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Rose, C , McMurray, R & Hadi, MU 2025, Digital Twin-Enabled Obstacle Avoidance System for the MADNI Drone. in 2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC). 2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC), IEEE, pp. 1-6, 2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC), Jamshoro, Pakistan, 23/04/25. https://doi.org/10.1109/icetecc65365.2025.11070262

Digital Twin-Enabled Obstacle Avoidance System for the MADNI Drone. / Rose, Cara ; McMurray, Robert ; Hadi, Muhammad Usman.
2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC). IEEE, 2025. p. 1-6 (2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC)).

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

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AU - McMurray, Robert

AU - Hadi, Muhammad Usman

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N2 - Obstacle avoidance is an essential ability for unmanned aerial vehicles (UAVs) operating in complex and dynamic environments. This work uses the Manoeuvrable Autonomous Drone for Navigation and Intelligence (MADNI) and integrates the 3D Vector Field Histogram Plus (3D VFH+) algorithm with Light Detection and Ranging (LiDAR) sensors to enhance real-time obstacle avoidance implemented on a digital twin of a real life UAV system. The 3D VFH+ algorithm enables MADNI to calculate optimal azimuth and pitch angles for safe navigation through obstacle-dense environments. LiDAR sensors provide high-precision, real-time spatial data, generating detailed three-dimensional environmental maps essential for detecting and avoiding obstacles. Integrating the 3D VFH+ algorithm with the LiDAR system allows MADNI to autonomously navigate through challenging environments with varying obstacle densities and configurations. The proposed system demonstrates its versatility in applications such as search and rescue (SAR) missions, surveillance, and environmental monitoring, enhancing safety, efficiency, and operational autonomy for UAV platforms.

AB - Obstacle avoidance is an essential ability for unmanned aerial vehicles (UAVs) operating in complex and dynamic environments. This work uses the Manoeuvrable Autonomous Drone for Navigation and Intelligence (MADNI) and integrates the 3D Vector Field Histogram Plus (3D VFH+) algorithm with Light Detection and Ranging (LiDAR) sensors to enhance real-time obstacle avoidance implemented on a digital twin of a real life UAV system. The 3D VFH+ algorithm enables MADNI to calculate optimal azimuth and pitch angles for safe navigation through obstacle-dense environments. LiDAR sensors provide high-precision, real-time spatial data, generating detailed three-dimensional environmental maps essential for detecting and avoiding obstacles. Integrating the 3D VFH+ algorithm with the LiDAR system allows MADNI to autonomously navigate through challenging environments with varying obstacle densities and configurations. The proposed system demonstrates its versatility in applications such as search and rescue (SAR) missions, surveillance, and environmental monitoring, enhancing safety, efficiency, and operational autonomy for UAV platforms.

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M3 - Conference contribution

SN - 979-8-3315-4338-9

SN - 979-8-3315-4339-6

T3 - 2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC)

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PB - IEEE

T2 - 2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC)

Y2 - 23 April 2025 through 25 April 2025

ER -

Rose C , McMurray R , Hadi MU. Digital Twin-Enabled Obstacle Avoidance System for the MADNI Drone. In 2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC). IEEE. 2025. p. 1-6. (2025 International Conference on Emerging Technologies in Electronics, Computing, and Communication (ICETECC)). Epub 2025 Jul 14. doi: 10.1109/icetecc65365.2025.11070262

Digital Twin-Enabled Obstacle Avoidance System for the MADNI Drone

Abstract

Publication series

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Bibliographical note

Keywords

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