Sliding mode control design for the attitude and altitude of the quadrotor UAV

Ahmed Eltayeb; Mohd Fua ad Rahmat; Mohd Ariffanan Mohd Basri

doi:10.21307/IJSSIS-2020-011

Sliding mode control design for the attitude and altitude of the quadrotor UAV

Ahmed Eltayeb
, Mohd Fua ad Rahmat^*
, Mohd Ariffanan Mohd Basri

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

23 Scopus citations

Abstract

Recently, the quadrotor unmanned aerial vehicles (UAV) are attracting significant interest from researchers due to its widespread applications, which involve the civilian and military sectors. In this paper, a robust sliding mode control (SMC) algorithm is designed to stabilize the attitude and track the altitude of quadrotor UAV. The switching function in the SMC control law has been replaced by the error function to reduce the chattering influences. The chattering phenomenon is induced by the parameter uncertainties and external disturbances and results in critical issues, for instance, the vibration in the mechanical components. The simulation results of the traditional SMC and feedback linearization (FBL) are used as the benchmark to test and evaluate the performance of the proposed SMC, which proved that the proposed controller outperforms the traditional SMC and FBL controllers.

Original language	English
Pages (from-to)	1-13
Number of pages	13
Journal	International Journal on Smart Sensing and Intelligent Systems
Volume	13
Issue number	1
DOIs	https://doi.org/10.21307/IJSSIS-2020-011
State	Published - Jan 2020
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2020 Authors.

Keywords

Chattering
Feedback linearization
PID control
Quadrotor UAV
Sliding mode control

ASJC Scopus subject areas

Control and Systems Engineering
Electrical and Electronic Engineering

Access to Document

10.21307/IJSSIS-2020-011

Cite this

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abstract = "Recently, the quadrotor unmanned aerial vehicles (UAV) are attracting significant interest from researchers due to its widespread applications, which involve the civilian and military sectors. In this paper, a robust sliding mode control (SMC) algorithm is designed to stabilize the attitude and track the altitude of quadrotor UAV. The switching function in the SMC control law has been replaced by the error function to reduce the chattering influences. The chattering phenomenon is induced by the parameter uncertainties and external disturbances and results in critical issues, for instance, the vibration in the mechanical components. The simulation results of the traditional SMC and feedback linearization (FBL) are used as the benchmark to test and evaluate the performance of the proposed SMC, which proved that the proposed controller outperforms the traditional SMC and FBL controllers.",

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AU - Eltayeb, Ahmed

AU - Rahmat, Mohd Fua ad

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AB - Recently, the quadrotor unmanned aerial vehicles (UAV) are attracting significant interest from researchers due to its widespread applications, which involve the civilian and military sectors. In this paper, a robust sliding mode control (SMC) algorithm is designed to stabilize the attitude and track the altitude of quadrotor UAV. The switching function in the SMC control law has been replaced by the error function to reduce the chattering influences. The chattering phenomenon is induced by the parameter uncertainties and external disturbances and results in critical issues, for instance, the vibration in the mechanical components. The simulation results of the traditional SMC and feedback linearization (FBL) are used as the benchmark to test and evaluate the performance of the proposed SMC, which proved that the proposed controller outperforms the traditional SMC and FBL controllers.

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Sliding mode control design for the attitude and altitude of the quadrotor UAV

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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