Trajectory Tracking Control for Quadrotor Robot Subject to Payload Variation and Wind Gust Disturbance

Chen Wang; Bifeng Song; Panfeng Huang; Changhong Tang

doi:10.1007/s10846-016-0333-4

Trajectory Tracking Control for Quadrotor Robot Subject to Payload Variation and Wind Gust Disturbance

Chen Wang, Bifeng Song, Panfeng Huang, Changhong Tang

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

104 Scopus citations

Abstract

This work proposes a hierarchical nonlinear control scheme for quadrotor to track 3D trajectory subject to payload variation and fast time-varying wind gust disturbance. In terms of dynamics model, the 6 DOF dynamics model with parametric and nonparametric uncertainties is built up. Wind gust and propeller momentum drag model are implemented to quantify the wind impact (force and moment disturbances) on quadrotor. In terms of control design, adaptive robust controller is developed for dynamic subsystem to deal with moment disturbance and estimate the system parameters. Global sliding mode controller is implemented for kinematic subsystem to generate adequate desired attitude angles for tracking the planned 3D trajectory. Simulations and experiments under various conditions are carried out for verification, and the results indicate the effectiveness, adaptiveness and robustness of the control strategy.

Original language	English
Pages (from-to)	315-333
Number of pages	19
Journal	Journal of Intelligent and Robotic Systems: Theory and Applications
Volume	83
Issue number	2
DOIs	https://doi.org/10.1007/s10846-016-0333-4
State	Published - 1 Aug 2016

Keywords

Adaptive robust control
Quadrotor robot
Sliding-mode control
Trajectory tracking
Wind gust

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10.1007/s10846-016-0333-4

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title = "Trajectory Tracking Control for Quadrotor Robot Subject to Payload Variation and Wind Gust Disturbance",

abstract = "This work proposes a hierarchical nonlinear control scheme for quadrotor to track 3D trajectory subject to payload variation and fast time-varying wind gust disturbance. In terms of dynamics model, the 6 DOF dynamics model with parametric and nonparametric uncertainties is built up. Wind gust and propeller momentum drag model are implemented to quantify the wind impact (force and moment disturbances) on quadrotor. In terms of control design, adaptive robust controller is developed for dynamic subsystem to deal with moment disturbance and estimate the system parameters. Global sliding mode controller is implemented for kinematic subsystem to generate adequate desired attitude angles for tracking the planned 3D trajectory. Simulations and experiments under various conditions are carried out for verification, and the results indicate the effectiveness, adaptiveness and robustness of the control strategy.",

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T1 - Trajectory Tracking Control for Quadrotor Robot Subject to Payload Variation and Wind Gust Disturbance

AU - Wang, Chen

AU - Song, Bifeng

AU - Huang, Panfeng

AU - Tang, Changhong

PY - 2016/8/1

Y1 - 2016/8/1

N2 - This work proposes a hierarchical nonlinear control scheme for quadrotor to track 3D trajectory subject to payload variation and fast time-varying wind gust disturbance. In terms of dynamics model, the 6 DOF dynamics model with parametric and nonparametric uncertainties is built up. Wind gust and propeller momentum drag model are implemented to quantify the wind impact (force and moment disturbances) on quadrotor. In terms of control design, adaptive robust controller is developed for dynamic subsystem to deal with moment disturbance and estimate the system parameters. Global sliding mode controller is implemented for kinematic subsystem to generate adequate desired attitude angles for tracking the planned 3D trajectory. Simulations and experiments under various conditions are carried out for verification, and the results indicate the effectiveness, adaptiveness and robustness of the control strategy.

AB - This work proposes a hierarchical nonlinear control scheme for quadrotor to track 3D trajectory subject to payload variation and fast time-varying wind gust disturbance. In terms of dynamics model, the 6 DOF dynamics model with parametric and nonparametric uncertainties is built up. Wind gust and propeller momentum drag model are implemented to quantify the wind impact (force and moment disturbances) on quadrotor. In terms of control design, adaptive robust controller is developed for dynamic subsystem to deal with moment disturbance and estimate the system parameters. Global sliding mode controller is implemented for kinematic subsystem to generate adequate desired attitude angles for tracking the planned 3D trajectory. Simulations and experiments under various conditions are carried out for verification, and the results indicate the effectiveness, adaptiveness and robustness of the control strategy.

KW - Adaptive robust control

KW - Quadrotor robot

KW - Sliding-mode control

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Trajectory Tracking Control for Quadrotor Robot Subject to Payload Variation and Wind Gust Disturbance

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