Robust error-based active disturbance rejection control of a quadrotor

Lechekhab, Taki Eddine; Manojlović, Stojadin M.; Stanković, Momir; Madoński, Rafał; Simić, S

doi:10.1108/aeat-12-2019-0266

Cited by 14 publications

(9 citation statements)

References 29 publications

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“…Remark 7. The presence of control signal u(t) in the total disturbance d(•), visible in (7), does not cause instability of the system as long as condition (5) is satisfied.…”

Section: Overview Of Implemented Adrc Algorithmmentioning

confidence: 99%

“…It is, however, recommended to be as precise as possible when setting the value b(•). Not only it can lead to the system instability when set outside the aforementioned acceptable range, but also can cause the total disturbance to be harder to estimate, since the difference between the real input gain parameter b(•) and its assumed value b(•) is incorporated within the total disturbance, represented by (7). Furthermore, when the value b(•) approaches the boundaries of ( 5), it may cause some unwanted oscillations in the system behavior.…”

Section: Estimate Of Input Gain B(•)mentioning

confidence: 99%

“…Analyzing the market and the scientific literature, one may find a variety of such software toolboxes supporting the synthesis of control systems, with emphasis on e.g. identification of dynamic systems [1], modeling and solving optimization problems [2], signal differentiators [3], disturbance observers [4], intelligent control based on brain emotional learning [5]), fractional-order control [6], or rapid prototyping [7].…”

Section: Introductionmentioning

confidence: 99%

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Active Disturbance Rejection Control (ADRC) Toolbox for MATLAB/Simulink

Giernacki¹,

Łakomy²,

Michalski³

et al. 2021

Preprint

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In this paper, an active disturbance rejection control (ADRC) toolbox for MAT-LAB/Simulink is introduced. Although ADRC has already been established as a powerful robust control framework with successful industrial implementations and strong theoretical foundations, a comprehensive tool for computer-aided design of ADRC has not been developed until now. The proposed ADRC Toolbox is a response to a growing need of both scientific community and control industry looking for a straightforward software utilization of the ADRC methodology. Its main purpose is to fill the gap between current theories and applications of ADRC and to provide an easy-to-use solution to users in various control fields wanting to employ the ADRC scheme in their applications. The ADRC Toolbox contains a single, general-purpose, drag-and-drop function block allowing to synthesize a predefined ADRC-based strategy with minimal design effort. Its efficacy is validated here in both simulations and hardware experiments, conducted using a variety of problems known from motion, process, and power control areas. The proposed ADRC Toolbox is an open-source project 1 .

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“…Remark 7. The presence of control signal u(t) in the total disturbance d(•), visible in (7), does not cause instability of the system as long as condition (5) is satisfied.…”

Section: Overview Of Implemented Adrc Algorithmmentioning

confidence: 99%

Section: Estimate Of Input Gain B(•)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Active Disturbance Rejection Control (ADRC) Toolbox for MATLAB/Simulink

Giernacki¹,

Łakomy²,

Michalski³

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…The error-based ADRC has been successfully applied by now to a variety of control problems including mechanical vibration compensation [21,22], robotic manipulator control [23,24], observer design with suppression of sensor noise [25][26][27], position control of a telescope mount [28], UAV control [29,30], as well as power electronics control [31,32].…”

Section: Introductionmentioning

confidence: 99%

Simplifying ADRC design with error-based framework: case study of a DC–DC buck power converter

Madoński

Łakomy

Yang

2021

Control Theory Technol.

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In this work, the problem of designing a robust control algorithm for a DC-DC buck power converter is investigated. The applied solution is based on a recently proposed error-based version of the active disturbance rejection control (ADRC) scheme, in which the unknown higher-order terms of the reference signal are treated as additional components of the system "total disturbance". The motivation here is to provide a practical following of a reference voltage trajectory for the buck converter in specific cases where neither the analytical form of the desired signal nor its future values are known a'priori, hence cannot be directly used for control synthesis. In this work, the application of the error-based ADRC results in a practically appealing control technique, with compact structure, simplified control rule, and intuitive tuning (inherited from the conventional output-based ADRC scheme). Theoretical, numerical, and experimental results are shown to validate the efficacy of the error-based ADRC in buck converter control, followed by a discussion about the revealed theoretical and practical limitations of this approach.

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“…In this study, we focus on the stability and performances of ADRC for multirotor UAVs when parametric uncertainties are not neglected. ADRC has already been successfully applied for the control of this kind of aerial vehicles, mostly on the attitude control loop like in Castillo et al (2016), Yang et al (2018), Yuan et al (2019) and Castillo et al (2019) or attitude and altitude as in Lechekhab et al (2020), but also for both position and attitude control like in Zhang et al (2018) and Xu et al (2020). It was demonstrated that the uncertainties on model parameters (the uncertainties of mass, inertia and actuation efficiency) can be considered as additional disturbances to be estimated by the observer and that they do not affect the stability under some conditions (existence of upper bounds).…”

mentioning

confidence: 99%

Robust active disturbance rejection control for systems with internal uncertainties: Multirotor UAV application

Chebbi

Brière

2022

Journal of Field Robotics

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Active Disturbance Rejection Control (ADRC) has recently stood out as a viable alternative to the proportional-integral-derivative controllers. An interesting field of application of this approach is the control of multirotor unmanned aerial vehicles (UAVs) which are inevitably subject to various force and torque disturbances. What makes ADRC attractive is the enhanced trajectory tracking and disturbance rejection capabilities that it allows while requiring minimal knowledge about the system.Although in theory, large uncertainties on the few required system parameters do not affect the stability of the ADRC's closed-loop, they cause performance deterioration and can lead to dangerous oscillations that result in instability in practice. In this study, we design a robust ADRC for multirotor UAVs that allows maintaining the performance despite large parameter variations, without changing the initial control gains tuning. Simulation and experimental results support the theoretical findings.

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Robust error-based active disturbance rejection control of a quadrotor

Cited by 14 publications

References 29 publications

Active Disturbance Rejection Control (ADRC) Toolbox for MATLAB/Simulink

Active Disturbance Rejection Control (ADRC) Toolbox for MATLAB/Simulink

Simplifying ADRC design with error-based framework: case study of a DC–DC buck power converter

Robust active disturbance rejection control for systems with internal uncertainties: Multirotor UAV application

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