Predictive modelling of quadrotor crash trajectory subjected to single and dual motor failures

Predictive modelling of quadrotor crash trajectory subjected to single and dual motor failures

Unmanned aerial vehicles (UAVs), specifically quadcopters, have seen a surge in utilization, playing critical roles in enhancing efficiency and effectiveness in the recreational and commercial sectors. However, despite its potential, quadcopters tend to have a higher failure rate, the most common be...

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Main Author: Yap, Nicholas Kit
Other Authors: Mir Feroskhan
Format: Final Year Project
Language:English
Published: Nanyang Technological University 2024
Subjects:
Engineering
Online Access:https://hdl.handle.net/10356/177495
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-1774952024-06-01T16:53:07Z Predictive modelling of quadrotor crash trajectory subjected to single and dual motor failures Yap, Nicholas Kit Mir Feroskhan School of Mechanical and Aerospace Engineering mir.feroskhan@ntu.edu.sg Engineering Unmanned aerial vehicles (UAVs), specifically quadcopters, have seen a surge in utilization, playing critical roles in enhancing efficiency and effectiveness in the recreational and commercial sectors. However, despite its potential, quadcopters tend to have a higher failure rate, the most common being propulsion failure. Although the public has recognised this flaw, the propulsion failure of a quadcopter has been understudied, with most available works of literature focused solely on the Complete Power Failure of a Quadcopter. To bridge this gap, RFlySim, which integrates MATLAB/Simulink and Pixhawk/PX4 software, has been utilised to conduct a comprehensive analysis of factors, including fluctuating thrust losses across various masses, failure time, and initial velocities to understand the crash trajectories of a quadcopter. In this study, both statistical and visual analyses were conducted. Simulation outcomes indicate that a hovering quadcopter with a Single Motor Failure has a crash radius of 10-meters whereas incorporating an initial velocity to a quadcopter result in a crash radius that is four times more. On the other hand, when Dual Rotor Failure is induced at a hovering state, crash points are predominantly concentrated at the origin, whereas at instances when an initial velocity was introduced, a higher concentration of crash occurrences occurred within the 15-to-40-meter zone. Beyond the simulation, prediction modelling was carried out with the LSTM model displaying superiority over other models in predicting the quadcopters’ crash trajectory with an MAE and RMSE value of 0.0146 and 0.0181. Bachelor's degree 2024-05-30T06:53:40Z 2024-05-30T06:53:40Z 2024 Final Year Project (FYP) Yap, N. K. (2024). Predictive modelling of quadrotor crash trajectory subjected to single and dual motor failures. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/177495 https://hdl.handle.net/10356/177495 en B153 application/pdf Nanyang Technological University
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Engineering
spellingShingle Engineering
Yap, Nicholas Kit
Predictive modelling of quadrotor crash trajectory subjected to single and dual motor failures
description Unmanned aerial vehicles (UAVs), specifically quadcopters, have seen a surge in utilization, playing critical roles in enhancing efficiency and effectiveness in the recreational and commercial sectors. However, despite its potential, quadcopters tend to have a higher failure rate, the most common being propulsion failure. Although the public has recognised this flaw, the propulsion failure of a quadcopter has been understudied, with most available works of literature focused solely on the Complete Power Failure of a Quadcopter. To bridge this gap, RFlySim, which integrates MATLAB/Simulink and Pixhawk/PX4 software, has been utilised to conduct a comprehensive analysis of factors, including fluctuating thrust losses across various masses, failure time, and initial velocities to understand the crash trajectories of a quadcopter. In this study, both statistical and visual analyses were conducted. Simulation outcomes indicate that a hovering quadcopter with a Single Motor Failure has a crash radius of 10-meters whereas incorporating an initial velocity to a quadcopter result in a crash radius that is four times more. On the other hand, when Dual Rotor Failure is induced at a hovering state, crash points are predominantly concentrated at the origin, whereas at instances when an initial velocity was introduced, a higher concentration of crash occurrences occurred within the 15-to-40-meter zone. Beyond the simulation, prediction modelling was carried out with the LSTM model displaying superiority over other models in predicting the quadcopters’ crash trajectory with an MAE and RMSE value of 0.0146 and 0.0181.
author2 Mir Feroskhan
author_facet Mir Feroskhan
Yap, Nicholas Kit
format Final Year Project
author Yap, Nicholas Kit
author_sort Yap, Nicholas Kit
title Predictive modelling of quadrotor crash trajectory subjected to single and dual motor failures
title_short Predictive modelling of quadrotor crash trajectory subjected to single and dual motor failures
title_full Predictive modelling of quadrotor crash trajectory subjected to single and dual motor failures
title_fullStr Predictive modelling of quadrotor crash trajectory subjected to single and dual motor failures
title_full_unstemmed Predictive modelling of quadrotor crash trajectory subjected to single and dual motor failures
title_sort predictive modelling of quadrotor crash trajectory subjected to single and dual motor failures
publisher Nanyang Technological University
publishDate 2024
url https://hdl.handle.net/10356/177495
_version_ 1814047100282863616

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