Fuzzy Optimized MFAC Based on ADRC in AUV Heading Control

Li, Hongjia; He, Bo; Yin, Qingqing; Mu, Xiaokai; Zhang, Jiaming; Wan, Junhe; Wang, Dianrui; Shen, Yue

doi:10.3390/electronics8060608

Cited by 28 publications

(12 citation statements)

References 34 publications

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“…Rodriguez et al [20] combine sliding mode control with adaptive control and propose a sliding mode adaptive controller, which is compared with non-adaptive control and PD control to verify the effectiveness of the controller. References [21][22][23][24][25] have made improvements based on the active disturbance rejection controller, combining sliding mode controller, self-searching optimal algorithm, or other methods, to improve the accuracy and anti-interference performance of the AUV motion control. In addition to the above methods, in recent years, scholars are also studying the application of reinforcement learning [26,27] and artificial intelligence algorithms [28] in the field of AUV control.…”

Section: Introductionmentioning

confidence: 99%

3-Dimensional Modeling and Attitude Control of Multi-Joint Autonomous Underwater Vehicles

Meng

Zhang

2021

JMSE

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To achieve rapid and flexible vertical profile exploration of deep-sea hybrid structures, a multi-joint autonomous underwater vehicle (MJ-AUV) with orthogonal joints was designed. This paper focuses on the 3-dimensional (3D) modeling and attitude control of the designed vehicle. Considering the situation of gravity and buoyancy imbalance, a 3D model of the MJ-AUV was established according to Newton’s second law and torque balance principle. And then the numerical simulation was carried out to verify the credibility of the model. To solve the problems that the pitch and yaw attitude of the MJ-AUV are coupled and the disturbance is unknown, a linear quadratic regulator (LQR) decoupling control method based on a linear extended state observer (LESO) was proposed. The system was decoupled into pitch and yaw subsystems, treated the internal forces and external disturbances of each subsystem as total disturbances, and estimated the total disturbances with LESO. The control law was divided into two parts. The first part was the total disturbance compensator, while the second part was the linear state feedback controller. The simulation results show that the overshoot of the controlled system in the dynamic process is nearly 0 rad, reaching the design value very smoothly. Moreover, when the controlled system is in a stable state, the control precision is within 0.005%.

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Section: Introductionmentioning

confidence: 99%

3-Dimensional Modeling and Attitude Control of Multi-Joint Autonomous Underwater Vehicles

Meng

Zhang

2021

JMSE

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“…During the last several decades, various control methods have been widely researched for trajectory tracking control problem of AUVs, such as the proportional-derivative (PD) control [ 5 ], the proportional integral derivative (PID) control [ 6 ], backstepping control (BSC) [ 7 ], sliding mode control (SMC) [ 8 ], fuzzy logic control (FLC) [ 9 ], neural-network-based control (NNC) [ 10 ], predictive control [ 11 ], adaptive control [ 12 ] and active disturbance rejection control (ADRC) [ 13 ]. Among them, the PD control and the PID control are the most used methods in practice due to their design simplicity and fine performance.…”

Section: Introductionmentioning

confidence: 99%

Antidisturbance Control for AUV Trajectory Tracking Based on Fuzzy Adaptive Extended State Observer

Kang

Rong

Chou

2020

Sensors

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In this paper, an output-feedback fuzzy adaptive dynamic surface controller (FADSC) based on fuzzy adaptive extended state observer (FAESO) is proposed for autonomous underwater vehicle (AUV) systems in the presence of external disturbances, parameter uncertainties, measurement noises and actuator faults. The fuzzy logic system is incorporated into both the observers and controllers to improve the adaptability of the entire system. The dynamics of the AUV system is established first, considering the external disturbances and parameter uncertainties. Based on the dynamic models, the ESO, combined with a fuzzy logic system tuning the observer bandwidth, is developed to not only adaptively estimate both system states and the lumped disturbances for the controller, but also reduce the impact of measurement noises. Then, the DSC, together with fuzzy logic system tuning the time constant of the low-pass filter, is designed using estimations from the FAESO for the AUV system. The asymptotic stability of the entire system is analyzed through Lyapunov’s direct method in the time domain. Comparative simulations are implemented to verify the effectiveness and advantages of the proposed method compared with other observers and controllers considering external disturbances, parameter uncertainties and measurement noises and even the actuator faults that are not considered in the design process. The results show that the proposed method outperforms others in terms of tracking accuracy, robustness and energy consumption.

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“…Compared with other model free control methods, MFAC algorithm has the following advantages. The training of neural network model needs huge data, so it is a challenge for data acquisition and processing [13]. PID control belongs to the category of model free control, but for the system of high nonlinearity and time-variability, the effect of PID control is not ideal [14].…”

Section: Introductionmentioning

confidence: 99%

MISO Model Free Adaptive Control of Single Joint Rehabilitation Robot Driven by Pneumatic Artificial Muscles

Liu

Meng

et al. 2020

2020 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM)

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Fuzzy Optimized MFAC Based on ADRC in AUV Heading Control

Cited by 28 publications

References 34 publications

3-Dimensional Modeling and Attitude Control of Multi-Joint Autonomous Underwater Vehicles

3-Dimensional Modeling and Attitude Control of Multi-Joint Autonomous Underwater Vehicles

Antidisturbance Control for AUV Trajectory Tracking Based on Fuzzy Adaptive Extended State Observer

MISO Model Free Adaptive Control of Single Joint Rehabilitation Robot Driven by Pneumatic Artificial Muscles

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