Ground crash area estimation of quadrotor aircraft under propulsion failure
Small unmanned aircraft systems or drones are expected to be used for different applications, such as parcel delivery, inspection, and aerial photography, in urban areas. However, drones usually use an electric system to power up the propulsion, communications, navigation, and flight control system,...
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sg-ntu-dr.10356-1673682023-05-20T16:49:01Z Ground crash area estimation of quadrotor aircraft under propulsion failure Mohd Hasrizam Che Man Sivakumar, Anush Kumar Hu, Haoliang Low, Kin Huat School of Mechanical and Aerospace Engineering Air Traffic Management Research Institute Engineering::Aeronautical engineering::Accidents and air safety Engineering::Aeronautical engineering::Aircraft motors and engines Engineering::Aeronautical engineering::Flight simulation Unmanned Aerial Vehicle Aircraft Flight Control System Quad Rotor Unmanned Aircraft Systems Propulsion System Failure Crash Trajectory Prediction Risk Analysis Safety Analysis High-Fidelity Modelling Small unmanned aircraft systems or drones are expected to be used for different applications, such as parcel delivery, inspection, and aerial photography, in urban areas. However, drones usually use an electric system to power up the propulsion, communications, navigation, and flight control system, which means that it is not as reliable as the manned aircraft system and may result in failure during operation and then crash to the ground. At present, there is almost no extensive publication about the high-fidelity modeling used by drones to calculate the crash trajectory and point of crash. The experimental data for modeling and simulation verification of multirotor aircraft are limited. So far, crash trajectory prediction has been limited to point mass or ballistic methods, and these methods are usually only suitable for complete power failure and without any control system. This study intends to investigate the effects of different multirotor drones’ failure modes on its crash trajectory and crash area compared to the ballistic model by using ADAMS and MATLAB co-simulation methods. Conclusions from the study show the crash trajectory, flight distance, and impact speed of the drones under four failure modes, which are quite different from the ballistic trajectory. The findings can potentially contribute to better risk assessment of the multirotor drones for the urban environment operation. Submitted/Accepted version 2023-05-18T07:32:06Z 2023-05-18T07:32:06Z 2023 Journal Article Mohd Hasrizam Che Man, Sivakumar, A. K., Hu, H. & Low, K. H. (2023). Ground crash area estimation of quadrotor aircraft under propulsion failure. Journal of Air Transportation. https://dx.doi.org/10.2514/1.D0320 2380-9450 https://hdl.handle.net/10356/167368 10.2514/1.D0320 en Journal of Air Transportation © 2023 by the American Institute of Aeronautics and Astronautics, Inc. All rights reserved. This paper was published in Journal of Air Transportation and is made available with permission of American Institute of Aeronautics and Astronautics, Inc. application/pdf |
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Engineering::Aeronautical engineering::Accidents and air safety Engineering::Aeronautical engineering::Aircraft motors and engines Engineering::Aeronautical engineering::Flight simulation Unmanned Aerial Vehicle Aircraft Flight Control System Quad Rotor Unmanned Aircraft Systems Propulsion System Failure Crash Trajectory Prediction Risk Analysis Safety Analysis High-Fidelity Modelling |
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Engineering::Aeronautical engineering::Accidents and air safety Engineering::Aeronautical engineering::Aircraft motors and engines Engineering::Aeronautical engineering::Flight simulation Unmanned Aerial Vehicle Aircraft Flight Control System Quad Rotor Unmanned Aircraft Systems Propulsion System Failure Crash Trajectory Prediction Risk Analysis Safety Analysis High-Fidelity Modelling Mohd Hasrizam Che Man Sivakumar, Anush Kumar Hu, Haoliang Low, Kin Huat Ground crash area estimation of quadrotor aircraft under propulsion failure |
| description |
Small unmanned aircraft systems or drones are expected to be used for different applications, such as parcel delivery, inspection, and aerial photography, in urban areas. However, drones usually use an electric system to power up the propulsion, communications, navigation, and flight control system, which means that it is not as reliable as the manned aircraft system and may result in failure during operation and then crash to the ground. At present, there is almost no extensive publication about the high-fidelity modeling used by drones to calculate the crash trajectory and point of crash. The experimental data for modeling and simulation verification of multirotor aircraft are limited. So far, crash trajectory prediction has been limited to point mass or ballistic methods, and these methods are usually only suitable for complete power failure and without any control system. This study intends to investigate the effects of different multirotor drones’ failure modes on its crash trajectory and crash area compared to the ballistic model by using ADAMS and MATLAB co-simulation methods. Conclusions from the study show the crash trajectory, flight distance, and impact speed of the drones under four failure modes, which are quite different from the ballistic trajectory. The findings can potentially contribute to better risk assessment of the multirotor drones for the urban environment operation. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Mohd Hasrizam Che Man Sivakumar, Anush Kumar Hu, Haoliang Low, Kin Huat |
| format |
Article |
| author |
Mohd Hasrizam Che Man Sivakumar, Anush Kumar Hu, Haoliang Low, Kin Huat |
| author_sort |
Mohd Hasrizam Che Man |
| title |
Ground crash area estimation of quadrotor aircraft under propulsion failure |
| title_short |
Ground crash area estimation of quadrotor aircraft under propulsion failure |
| title_full |
Ground crash area estimation of quadrotor aircraft under propulsion failure |
| title_fullStr |
Ground crash area estimation of quadrotor aircraft under propulsion failure |
| title_full_unstemmed |
Ground crash area estimation of quadrotor aircraft under propulsion failure |
| title_sort |
ground crash area estimation of quadrotor aircraft under propulsion failure |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/167368 |
| _version_ |
1772829023587532800 |