Adaptive unit vector control of multivariable systems using monitoring functions

Hsu, Liu; Oliveira, Tiago Roux; Cunha, José Paulo V. S.; Lin, Yan

doi:10.1002/rnc.4253

Cited by 37 publications

(33 citation statements)

References 37 publications

(97 reference statements)

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“…In which ξ w = ξ 4 ξ 5 ξ 6 T is the first-order wave motion component. Assumption 6: The only directly measured state is the vessel 2D position and attitude composed of both the lowfrequency and wave-frequency motions (11). The filter estimates other system states required for control feedback.…”

Section: Mathematical Modelmentioning

confidence: 99%

“…In [9] and in [10], numerical and experimental results for SMCs with notch wave filtering have been produced and discussed. An approach for multivariable SMC control of a Surface Vessel was presented in [11], not addressing, however, the state estimation problem and high-frequency wave filtering. In [12], the SM controller with feedback from a Nonlinear Passive Observer was proposed.…”

Section: Introductionmentioning

confidence: 99%

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Robust Output-Feedback Control in a Dynamic Positioning System via High Order Sliding Modes: Theoretical Framework and Experimental Evaluation

2020

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Despite being an established and mature technology, Vessel Dynamic Positioning Systems are always in focus for the development of novel control applications in order to increase their operational capacities. Rapid and robust transient response without loss of control accuracy is, for instance, a requirement for autonomous operations. Standard technologies currently applied by the industry lack such properties. Emerging methods, such as nonlinear robust control techniques, may help to achieve this goal. This paper proposes using a Super-Twisting Controller, allied with a High Order Sliding Mode Observer to perform the Dynamic Positioning Task. This method provides the robustness of standard Sliding Modes Controllers while keeping accuracy and chattering suppression. A novel nonlinear sliding manifold and wave-frequency filtering is proposed for the Dynamic Positioning problem. The efficacy of this control structure is demonstrated in a series of experimental tests, whereby the subject vessel is controlled while disturbed by wave action. INDEX TERMS Dynamic positioning systems, super-twisting control, high order sliding modes, robust nonlinear control.

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Section: Mathematical Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Robust Output-Feedback Control in a Dynamic Positioning System via High Order Sliding Modes: Theoretical Framework and Experimental Evaluation

2020

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“…The tracking control for nonlinear systems has attracted many scholars to engage in both theoretical and application research. [1][2][3][4] Especially, after backstepping method, one of the most popular controller design methods, was proposed, 5 many control methods were combined to achieve tracking control for nonlinear systems, such as H ∞ control, adaptive control, sliding mode, dynamic surface, fuzzy/neural approximation, and so on. There have been many relevant achievements in this area for different types of nonlinear systems, such as switched systems, multiple input multiple output (MIMO) systems, stochastic systems, discrete-time systems, time-varying systems, and fractional systems.…”

Section: Introductionmentioning

confidence: 99%

“…The tracking control for nonlinear systems has attracted many scholars to engage in both theoretical and application research 1‐4 . Especially, after backstepping method, one of the most popular controller design methods, was proposed, 5 many control methods were combined to achieve tracking control for nonlinear systems, such as H ∞ control, adaptive control, sliding mode, dynamic surface, fuzzy/neural approximation, and so on.…”

Section: Introductionmentioning

confidence: 99%

Event‐triggered adaptive finite‐time prescribed performance tracking control for uncertain nonlinear systems

Liu

Wang

et al. 2020

Intl J Robust & Nonlinear

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This article addresses the problem of adaptive finite-time tracking control for unknown nonlinear systems based on event-triggered and prescribed performance control. For the first time, a new adjustable finite-time performance function is developed, whose parameters are adjusted online with the change of tracking errors so that it converges faster. Besides, a novel event-triggered control method is introduced to switch smoothly between the fixed and relative threshold strategies. Finally, an adaptive finite-time tracking controller is constructed, which ensures the boundness of all the signals in the closed-loop system and elimination of the Zeno behavior. Simultaneously, the output tracking error falls in a fixed region at pre-defined finite time.

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“…No entanto, o conjunto residual não podia ser completamente caracterizado. Esse problema foi superado em Hsu et al (2019). Além disso, loc.…”

Section: Introductionunclassified

Controle Vetorial Unitário Adaptativo via Funções de Barreira e Monitoração

Rodrigues

Hsu

Oliveira

et al. 2020

Anais Do Congresso Brasileiro De Automática 2020

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Este artigo propõe uma nova abordagem para o controle vetorial unitário adaptativo via realimentação de saída para uma classe de sistemas não-lineares multivariáveis. O controlador baseado em modo deslizante pode lidar com incertezas paramétricas e perturbações casadas e/ou descasadas com limitantes superiores desconhecidos. A convergência em tempo finito do erro de rastreamento à uma vizinhança predefinida da origem do sistema em malha fechada é garantida com desempenho transitório preestabelecido. Basicamente, a novidade de nosso resultado está na combinação de duas importantes ferramentas de adaptação: funções monitoração e de barreira. O processo de adaptação é dividido em duas fases, em uma a função de monitoração permite a especificação de critérios de desempenho durante a fase transitória, inclusive com convergência em tempo finito, enquanto na outra a função de barreira limita o erro de rastreamento à um pequeno conjunto residual. Os resultados de simulação ilustram a eficiência da estratégia de controle adaptativo proposta.

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Adaptive unit vector control of multivariable systems using monitoring functions

Cited by 37 publications

References 37 publications

Robust Output-Feedback Control in a Dynamic Positioning System via High Order Sliding Modes: Theoretical Framework and Experimental Evaluation

Robust Output-Feedback Control in a Dynamic Positioning System via High Order Sliding Modes: Theoretical Framework and Experimental Evaluation

Event‐triggered adaptive finite‐time prescribed performance tracking control for uncertain nonlinear systems

Controle Vetorial Unitário Adaptativo via Funções de Barreira e Monitoração

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