Saturation based nonlinear PID control for underwater vehicles: Design, stability analysis and experiments

Guerrero, Jesús; Torres, J.; Creuze, Vincent; Chemori, Ahmed; Campos, E.

doi:10.1016/j.mechatronics.2019.06.006

Cited by 63 publications

(39 citation statements)

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“…Remark 6. It is worth to notice that in this manuscript is different from the work presented in [19]. On one hand, in study [19], a nonlinear PID was proposed while in this work, we propose the improvement of the nonlinear PD proposed by [18].…”

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confidence: 83%

“…However, it is well-known that the performance of the PD/PID controller is degraded when the plant is highly nonlinear or time-varying. To overcome these drawbacks, the PD/PID controllers are improved adopting strategies based on auto-adjustable [15], saturated [16], adaptive [17], or nonlinear functions [18,19]. For instance, a nonlinear PID for the trajectory tracking of an AUV is proposed in Guerrero et al [19].…”

Section: Several Strategies Have Been Proposed To Control Underwater mentioning

confidence: 99%

“…To overcome these drawbacks, the PD/PID controllers are improved adopting strategies based on auto-adjustable [15], saturated [16], adaptive [17], or nonlinear functions [18,19]. For instance, a nonlinear PID for the trajectory tracking of an AUV is proposed in Guerrero et al [19]. In this work, a PID was saturated by a whole set of nonlinear functions in order to provide robustness towards external disturbances and parametric uncertainties.…”

Section: Several Strategies Have Been Proposed To Control Underwater mentioning

confidence: 99%

“…On one hand, in study [19], a nonlinear PID was proposed while in this work, we propose the improvement of the nonlinear PD proposed by [18]. On the other hand, in this manuscript, we use sliding mode theory to improve a PD controller while in work [19] is an extension of the saturated based-control.…”

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confidence: 99%

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Adaptive disturbance observer for trajectory tracking control of underwater vehicles

et al. 2020

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Complex and highly coupled dynamics, time-variance, unpredictable disturbances and lack of knowledge of hydrodynamic parameters, complicate the control of underwater vehicles. This paper deals with the adaptive disturbance observer design for the robust trajectory tracking problem for underwater vehicles in presence of unknown external disturbances and parametric uncertainties. First, the dynamics of the vehicle is transformed into the socalled regular form. Then, based on the Extended State Observer technique and High Order Sliding Modes Control, a disturbance observer is proposed. Furthermore, the gains of the observer are automatically adjusted by the introduction of an adaption law. The stability of the whole controller/observer scheme is proven using Lyapunov's arguments. The adaptive disturbance observer aims to improve the Backstepping and nonlinear PD controllers. Real-Time experiments demonstrate the effectiveness of the proposed algorithm for the trajectory tracking task under several scenarios.

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confidence: 83%

Section: Several Strategies Have Been Proposed To Control Underwater mentioning

confidence: 99%

Section: Several Strategies Have Been Proposed To Control Underwater mentioning

confidence: 99%

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confidence: 99%

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Adaptive disturbance observer for trajectory tracking control of underwater vehicles

et al. 2020

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“…As a consequence, the design of a tracking control scheme for the such vehicles becomes a critical issue [9]. Indeed, several control schemes have been proposed in the literature to address this problem, such as improved control schemes based on PD and PID control [10] [11] [12], robust control [13], adaptive control [14], intelligent and hybrid control [15].…”

Section: Introductionmentioning

confidence: 99%

Robust Adaptive Tracking Control of Underwater Vehicles: Design, Stability Analysis, and Experiments

Tijjani

Chemori

Creuze

2021

IEEE/ASME Trans. Mechatron.

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Auxiliary model‐based iterative parameter estimation for a nonlinear output‐error system with saturation and dead‐zone nonlinearity

Wang

Ding

Alsaedi

et al. 2021

Intl J Robust & Nonlinear

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This article is concerned with the parameter estimation problem of a nonlinear output‐error system with saturation and dead‐zone nonlinearity. The saturation nonlinearities and the dead‐zone nonlinearities are widely encountered in engineering applications and the identification for the nonlinear systems with these nonlinearities is very crucial. Based on the over‐parameterization identification model and the auxiliary model identification idea, an auxiliary model least‐squares‐based iterative algorithm is presented for estimating the parameters of the nonlinear system with saturation and dead‐zone nonlinearity. In order to enhance the computational efficiency, an auxiliary model gradient‐based iterative algorithm is presented for the nonlinear system. Using the multi‐innovation identification theory, an auxiliary model multi‐innovation gradient‐based iterative algorithm is derived for tracking time‐varying parameters. An example is carried out to show the effectiveness of the proposed algorithms. The numerical simulation results show that all the proposed algorithms can generate accurate parameter estimates.

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Saturation based nonlinear PID control for underwater vehicles: Design, stability analysis and experiments

Cited by 63 publications

References 20 publications

Adaptive disturbance observer for trajectory tracking control of underwater vehicles

Adaptive disturbance observer for trajectory tracking control of underwater vehicles

Robust Adaptive Tracking Control of Underwater Vehicles: Design, Stability Analysis, and Experiments

Auxiliary model‐based iterative parameter estimation for a nonlinear output‐error system with saturation and dead‐zone nonlinearity

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