Adaptive Neural Motion Control of a Quadrotor UAV

Yañez-Badillo, Hugo; Tapia‐Olvera, Ruben; Beltrán-Carbajal, Francisco

doi:10.3390/vehicles2030026

Cited by 6 publications

(1 citation statement)

References 35 publications

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“…where the altitude of the system is described by the set of Euler angles φ, θ, and ψ, and the position by the x, y, and z coordinates, both regarding the inertial reference frame I, as depicted in Figure 1. In the present study, the following nonlinear dynamic model of the quadrotor is considered [8,51,53,54]:…”

Section: Nonlinear Four-rotor Aerial Vehicle Dynamicsmentioning

confidence: 99%

On Active Vibration Absorption in Motion Control of a Quadrotor UAV

Beltrán-Carbajal

Yañez-Badillo²,

Tapia‐Olvera

et al. 2022

Mathematics

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Conventional dynamic vibration absorbers are physical control devices designed to be coupled to flexible mechanical structures to be protected against undesirable forced vibrations. In this article, an approach to extend the capabilities of forced vibration suppression of the dynamic vibration absorbers into desired motion trajectory tracking control algorithms for a four-rotor unmanned aerial vehicle (UAV) is introduced. Nevertheless, additional physical control devices for mechanical vibration absorption are unnecessary in the proposed motion profile reference tracking control design perspective. A new dynamic control design approach for efficient tracking of desired motion profiles as well as for simultaneous active harmonic vibration absorption for a quadrotor helicopter is then proposed. In contrast to other control design methods, the presented motion tracking control scheme is based on the synthesis of multiple virtual (nonphysical) dynamic vibration absorbers. The mathematical structure of these physical mechanical devices, known as dynamic vibration absorbers, is properly exploited and extended for control synthesis for underactuated multiple-input multiple-output four-rotor nonlinear aerial dynamic systems. In this fashion, additional capabilities of active suppression of vibrating forces and torques can be achieved in specified motion directions on four-rotor helicopters. Moreover, since the dynamic vibration absorbers are designed to be virtual, these can be directly tuned for diverse operating conditions. In the present study, it is thus demonstrated that the mathematical structure of physical mechanical vibration absorbers can be extended for the design of active vibration control schemes for desired motion trajectory tracking tasks on four-rotor aerial vehicles subjected to adverse harmonic disturbances. The effectiveness of the presented novel design perspective of virtual dynamic vibration absorption schemes is proved by analytical and numerical results. Several operating case studies to stress the advantages to extend the undesirable vibration attenuation capabilities of the dynamic vibration absorbers into trajectory tracking control algorithms for nonlinear four-rotor helicopter systems are presented.

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Section: Nonlinear Four-rotor Aerial Vehicle Dynamicsmentioning

confidence: 99%

On Active Vibration Absorption in Motion Control of a Quadrotor UAV

Beltrán-Carbajal

Yañez-Badillo²,

Tapia‐Olvera

et al. 2022

Mathematics

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Advanced Machine Learning Detection using UAV Motion Tracking and Control

Bala

Verma

2023

2023 International Conference on Distributed Computing and Electrical Circuits and Electronics (ICDCECE)

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Neural Adaptive Robust Motion-Tracking Control for Robotic Manipulator Systems

et al. 2022

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This paper deals with the motion trajectory tracking control problem based on output feedback and artificial neural networks for anthropomorphic manipulator robots under disturbed operating scenarios. This class of manipulator robots constitutes nonlinear dynamic systems subjected to disturbance torques induced mainly by work payload. Parametric uncertainty and possible dynamic modeling errors stand for other kind of disturbances that can deteriorate the efficiency and robustness of the tracking of controlled nonlinear robotic system trajectories. In fact, the presence of unknown dynamic disturbances is unavoidable in industrial robotic engineering systems. Therefore, for high-precision applications, such as laser cutting, marking, or welding, effective control schemes should be designed to guarantee adequate motion profile tracking planned on this class of disturbed nonlinear robotic system. In this context, a new adaptive robust motion trajectory tracking control scheme based on output feedback and artificial neural networks of anthropomorphic manipulator robots is presented. Three-layer B-spline artificial neural networks and time-series modeling are properly exploited in the design of novel adaptive robust motion tracking controllers for robotic applications of laser manufacturing. In this way, dependency on detailed nonlinear mathematical modeling of robotic systems is considerably reduced, and real-time estimation of uncertain dynamic disturbances is not required. Furthermore, several cases studies to demonstrate the motion planning tracking control robustness for a class of MIMO nonlinear robotic systems are described. blue Insights for the extension of the introduced output-feedback adaptive neural control design approach for other architecture of nonlinear robotic systems are depicted.

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Adaptive Neural Motion Control of a Quadrotor UAV

Cited by 6 publications

References 35 publications

On Active Vibration Absorption in Motion Control of a Quadrotor UAV

On Active Vibration Absorption in Motion Control of a Quadrotor UAV

Advanced Machine Learning Detection using UAV Motion Tracking and Control

Neural Adaptive Robust Motion-Tracking Control for Robotic Manipulator Systems

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