Different‐factor compact‐form model‐free adaptive control with neural networks for MIMO nonlinear systems

Chen, Chen; Lu, Jiangang

doi:10.1002/asjc.2555

Cited by 7 publications

(4 citation statements)

References 32 publications

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“…y u (29) where u(k) ∈ R m and y(k) ∈ R, respectively, represent the input and output of the system at time k; n u and n y are the orders of the input and output of the system, respectively;…”

Section: Model-free Adaptive Control Of the Leaching Processmentioning

confidence: 99%

“…The learning parameters are auto-tuned by back propagation neural networks. This control algorithm has been successfully applied to coal mill system . Combining a sampled-data parameter estimator to estimate the unknown partial derivatives and a sampled-data observer to estimate the residual nonlinear uncertainty, an observer-based SMFAC scheme has been proposed for continuous-time nonlinear nonaffine systems with input constraints.…”

Section: Introductionmentioning

confidence: 99%

“…This control algorithm has been successfully applied to coal mill system. 29 Combining a sampled-data parameter estimator to estimate the unknown partial derivatives and a sampled-data observer to estimate the residual nonlinear uncertainty, an observer-based SMFAC scheme has been proposed for continuous-time nonlinear nonaffine systems with input constraints. The constraint on the input rate is also considered in the control law as the transition condition.…”

Section: Introductionmentioning

confidence: 99%

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Model-Free Adaptive Control of Hydrometallurgy Cascade Gold Leaching Process with Input Constraints

et al. 2023

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Hydrometallurgy technology can directly deal with low grade and complex materials, improve the comprehensive utilization rate of resources, and effectively adapt to the demand of low carbon and cleaner production. A series of cascade continuous stirred tank reactors are usually applied in the gold leaching industrial process. The equations of leaching process mechanism model are mainly composed of gold conservation, cyanide ion conservation, and kinetic reaction rate equations. The derivation of the theoretical model involves many unknown parameters and some ideal assumptions, which leads to difficulty and imprecision in establishing the accurate mechanism model of the leaching process. Imprecise mechanism models limit the application of model-based control algorithms in the leaching process. Due to the constraints and limitations of the input variables in the cascade leaching process, a novel model-free adaptive control algorithm based on compact form dynamic linearization with integration (ICFDL-MFAC) control factor is first constructed. The constraints between input variables is realized by setting the initial value of the input to the pseudo-gradient and the weight of the integral coefficient. The proposed pure data-driven ICFDL-MFAC algorithm has anti-integral saturation ability and can achieve faster control rate and higher control precision. This control strategy can effectively improve the utilization efficiency of sodium cyanide and reduce environmental pollution. The consistent stability of the proposed control algorithm is also analyzed and proved. Compared with the existing model-free control algorithms, the merit and practicability of the control algorithm are verified by the practical leaching industrial process test. The proposed model-free control strategy has advantages of strong adaptive ability, robustness, and practicability. The MFAC algorithm can also be easily applied to control the multi-input multi-output of other industrial processes.

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Section: Model-free Adaptive Control Of the Leaching Processmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Model-Free Adaptive Control of Hydrometallurgy Cascade Gold Leaching Process with Input Constraints

et al. 2023

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“…For the car‐like mobile robot systems, the literature [18] proposes a data‐driven generalized predictive control method based on interval type‐2 T‐S fuzzy neural network, which does not rely on the mathematical model of the mobile robot but only on the historical data of its operation. Literature [19] proposes a model‐free adaptive control method based on compact neural network with different factor structures for a kind of general MIMO systems using data‐driven control technology. In order to suppress the influence of system parameter changes, a nonlinear model‐based predictive control strategy for constrained systems based on an adaptive neural network predictor is proposed in literature [20].…”

Section: Introductionmentioning

confidence: 99%

Model‐free predictive control for a class of asymmetric nonlinear systems

Tian

Wang

2023

Asian Journal of Control

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A model‐free predictive control (MFPC) method is proposed for a kind of discrete nonlinear asymmetric systems (NASs) whose models are undefined. According to the dynamic characteristics of the asymmetric system, the compact format dynamic linearization (CFDL) technology and the improved projection algorithm are adopted to set up models for the controlled NAS. Then, based on the estimation models, the explicit analytical solution of the controller is obtained by solving the quadratic function of finite‐time domain rolling optimization. Finally, a switching law is designed to make the system switch reasonably between the positive and negative models, thus ensuring the stability of the whole system. The effectiveness of the proposed method is testified by a simulation example.

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Model complexity optimization of equivalent dynamical linearization data models used in model‐free adaptive control

Salighe,

Söffker

2024

Proc Appl Math and Mech

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This paper discusses a strategy for optimizing the complexity of time‐varying data models as used in model‐free adaptive control (MFAC). Here the dynamic linearization in compact form (CFDL), partial form (PFDL), and full form (FFDL) are considered as data models used to describe input/output (I/O) data sets. These data models are built only for control purpose and can have various degrees of complexity depending on the size of the considered time‐window as well as the underlying algorithms. The methodology is to compare the performance of the data models according to an evaluation criterion, to analyze the order of different data models based on bias‐variance trade‐off, and to select the best‐performing model. The complexity of the selected model is compared with the reduced linear time‐invariant (LTI) model obtained by applying a combination of the eigensystem realization algorithm (ERA) and observer/Kalman filter identification (OKID) on the same I/O dataset. The I/O data are obtained from applying the MFAC controllers on a nonlinear three‐tank system (3TS) to track various desired references. The results indicate that the model complexity optimization can also be used for selecting an appropriate MFAC data model with optimal order to reduce the complexity and computational burden of the MFAC control algorithms.

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Different‐factor compact‐form model‐free adaptive control with neural networks for MIMO nonlinear systems

Cited by 7 publications

References 32 publications

Model-Free Adaptive Control of Hydrometallurgy Cascade Gold Leaching Process with Input Constraints

Model-Free Adaptive Control of Hydrometallurgy Cascade Gold Leaching Process with Input Constraints

Model‐free predictive control for a class of asymmetric nonlinear systems

Model complexity optimization of equivalent dynamical linearization data models used in model‐free adaptive control

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