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Erschienen in:
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2024 | OriginalPaper | Buchkapitel

A Comparative Study of PID and Nonlinear Backstepping Flight Control Laws for Pixhawk-Based Multicopter

verfasst von : Divyansh Singh, Hari Om Verma, Vivek Kumar, Rajesh K. Saluja, Sanjay Singh, Keerthana Radhakrishnan

Erschienen in: Recent Advances in Aerospace Engineering

Verlag: Springer Nature Singapore

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Abstract

This paper investigates the control strategies for a quadcopter UAV controlled by a Pixhawk-based flight controller. First, the nonlinear mathematical model of a quadcopter has been derived considering its aerodynamic and rotor effects. From this model, it can be seen that the quadcopter is a nonlinear underactuated system which makes its control design challenging. Two control approaches for this quadcopter system have been chosen and analysed here, the linear proportional–integral–derivative (PID) control and the nonlinear Backstepping control approach. Both approaches were adapted for use in the PX4-Pixhawk-based controllers. Their performance was tested with a quadcopter dynamic model and the results were simulated. A comparison of the obtained results indicates that the Backstepping control technique settles > 5 times faster than the PID control and also provides more stability to the system making it the preferable control strategy for quadcopters using Pixhawk-based autopilots.

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Vorheriges Kapitel Machine Learning Assisted Development of Eight Node Hexahedral Finite Element
Nächstes Kapitel Countering Drone Using a Mountable Net Mechanism
Literatur
1.
Bresciani T (2008) Modelling, identification and control of a quadrotor helicopter. Master’s thesis, Lund University
2.
Hoffmann G, Huang H, Waslander S, Tomlin C (2007) Quadrotor helicopter flight dynamics and control: Theory and experiment. In: Proceedings of the AIAA guidance, navigation, and control conference, 2007, pp 1–20
3.
de Oliveira MDLC (2011) Modelling, identification and control of a quadrotor aircraft. Master’s thesis, Czech Technical University in Prague
4.
Balas C (2006) Modelling and linear control of a quadrotor. Cranfield Unicersity, M.Sc. thesis, vol 2007
5.
Al-Younes Y, Al-Jarrah M, Jhemi A (2010) Linear versus nonlinear control techniques for a quadrotor vehicle. In: 7th International symposium on mechatronics and its applications (ISMA), IEEE, 2010, pp 1–10
6.
Bouabdallah S (2007) Design and control of quadrotors with application to autonomous flying. Ph.D. dissertation, Federal Polytechnic School of Lausanne
7.
Madani T, Benallegue A (2006) Backstepping control for a quadrotor helicopter. In: 2006 IEEE/RSJ international conference on intelligent robots and systems, 2006, pp 3255–3260
8.
Whitehead B, Bieniawski S (2010) Model reference adaptive control of a quadrotor UAV. In: The AIAA Guidance Navigation and Control Conference, Canada, 2010.
9.
Huang M, Xian B, Diao C, Yang K, Feng Y (2010) Adaptive tracking control of underactuated quadrotor unmanned aerial vehicles via backstepping. In: American control conference (ACC), 2010, pp 2076–2081
10.
Bouabdallah S, Siegwart R (2005) Backstepping and sliding-mode techniques applied to an indoor micro quadrotor. In: International conference on robotics and automation, 2005, pp 2247–2252
Metadaten
Titel
A Comparative Study of PID and Nonlinear Backstepping Flight Control Laws for Pixhawk-Based Multicopter
verfasst von
Divyansh Singh
Hari Om Verma
Vivek Kumar
Rajesh K. Saluja
Sanjay Singh
Keerthana Radhakrishnan
Copyright-Jahr
2024
Verlag
Springer Nature Singapore
Buch
Recent Advances in Aerospace Engineering

Print ISBN: 978-981-9713-05-9

Electronic ISBN: 978-981-9713-06-6

Copyright-Jahr: 2024

DOI
https://doi.org/10.1007/978-981-97-1306-6_21

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