Model Predictive Control Based on Linear Parameter-Varying Models of Active Magnetic Bearing Systems

Active magnetic bearing (AMB) system has been recently employed widely as an ideal equipment for high-speed rotating machines. The inherent challenges to control the system include instability, nonlinearity and constricted range of operation. Therefore, advanced control technology is essential to optimize AMB system performance. This paper presents an application of model predictive control (MPC) based on linear parameter-varying (LPV) models to control an AMB system subject to input and state constraints. For this purpose, an LPV model representation is derived from the nonlinear dynamic model of the AMB system. In order to provide stability guarantees and since the obtained LPV model has a large number of scheduling parameters, the parameter set mapping (PSM) technique is used to reduce their number. Based on the reduced model, a terminal cost and an ellipsoidal terminal set are determined offline and included into the MPC optimization problem which are the essential ingredients for guaranteeing the closed-loop asymptotic stability. Moreover, for recursive feasibility of the MPC optimization problem, a slack variable is included into its cost function. The goal of the proposed feedback control system is twofold. First is to demonstrate high performance by achieving stable levitation of the rotor shaft as well as high capability of reference tracking without violating input and state constraints, which increases the overall safety of the system under disturbances effects. Second is to provide a computationally tractable LPVMPC algorithm, which is a substantial requirement in practice for operating the AMB system with high performance over its full range. Therefore, we propose an LPVMPC scheme with frozen scheduling parameter over the prediction horizon of the MPC. Furthermore, we demonstrate in simulation that such frozen LPVMPC can achieve comparable performance to a more sophisticated LPVMPC scheme developed recently and a standard NL MPC (NMPC) approach. Moreover, to verify the performance of the proposed frozen LPVMPC, a comparison with a classical controller, which is commonly applied to the system in practice, is provided.

[1]  Herbert Werner,et al.  PCA-Based Parameter Set Mappings for LPV Models With Fewer Parameters and Less Overbounding , 2008, IEEE Transactions on Control Systems Technology.

[2]  Zhaobo Chen,et al.  A Dual-Loop Control Approach of Active Magnetic Bearing System for Rotor Tracking Control , 2019, IEEE Access.

[3]  Hms Hossam Abbas,et al.  An improved robust model predictive control for linear parameter‐varying input‐output models , 2018 .

[4]  Guangdeng Zong,et al.  Observed-based adaptive finite-time tracking control for a class of nonstrict-feedback nonlinear systems with input saturation , 2020, J. Frankl. Inst..

[5]  Akhtar Kalam,et al.  Robust control of an active magnetic bearing system using H∞ and disturbance observer-based control , 2017 .

[6]  C. Kelley Solving Nonlinear Equations with Newton's Method , 1987 .

[7]  Seyed Mahdi Hashemi,et al.  LPV state-feedback control of a control moment gyroscope , 2014 .

[8]  Franco Blanchini,et al.  Set-theoretic methods in control , 2007 .

[9]  Ramon Costa-Castelló,et al.  A Model Predictive Control-Based Energy Management Scheme for Hybrid Storage System in Islanded Microgrids , 2020, IEEE Access.

[10]  Jan M. Maciejowski,et al.  Predictive control : with constraints , 2002 .

[11]  Christian Hoffmann,et al.  A Survey of Linear Parameter-Varying Control Applications Validated by Experiments or High-Fidelity Simulations , 2015, IEEE Transactions on Control Systems Technology.

[12]  Abdelfatah M. Mohamed,et al.  Modeling and robust control of self-sensing magnetic bearings with unbalance compensation , 1997, Proceedings of the 1997 IEEE International Conference on Control Applications.

[13]  Jiancheng Fang,et al.  Mismatched Disturbance Rejection Control for Voltage-Controlled Active Magnetic Bearing via State-Space Disturbance Observer , 2015, IEEE Transactions on Power Electronics.

[14]  G. Schweitzer,et al.  Magnetic bearings : theory, design, and application to rotating machinery , 2009 .

[15]  Drago Dolinar,et al.  Active magnetic bearings control , 2010, Proceedings of the 29th Chinese Control Conference.

[16]  Christian Hoffmann,et al.  Tube-based model predictive control for linear parameter-varying systems with bounded rate of parameter variation , 2019, Autom..

[17]  Yi Chang,et al.  Adaptive Fuzzy Output-Feedback Tracking Control for Switched Nonstrict-Feedback Nonlinear Systems with Prescribed Performance , 2020, Circuits Syst. Signal Process..

[18]  Seyed Mahdi Hashemi,et al.  Low-complexity linear parameter-varying modeling and control of a robotic manipulator , 2012 .

[19]  Gang Liu,et al.  Feedback Linearization and Extended State Observer-Based Control for Rotor-AMBs System With Mismatched Uncertainties , 2017, IEEE Transactions on Industrial Electronics.

[20]  P. S. V. Nataraj,et al.  A Stabilizing Sub-Optimal Model Predictive Control for Quasi-Linear Parameter Varying Systems , 2020, IEEE Control Systems Letters.

[21]  Peter Klaus Budig Magnetic bearings and some new applications , 2011 .

[22]  David Q. Mayne,et al.  Constrained model predictive control: Stability and optimality , 2000, Autom..

[23]  J. Edward Jackson,et al.  A User's Guide to Principal Components. , 1991 .

[24]  Roland Tóth,et al.  Stabilizing Tube-Based Model Predictive Control: Terminal Set and Cost Construction for LPV Systems (extended version) , 2017, Autom..

[25]  Hossam S. Abbas,et al.  Wind turbine control based on a modified model predictive control scheme for linear parameter-varying systems , 2017 .

[26]  Kuan-Yu Chen,et al.  A self-tuning fuzzy PID-type controller design for unbalance compensation in an active magnetic bearing , 2009, Expert Syst. Appl..

[27]  Hossam S. Abbas,et al.  Model Predictive Control for an Active Magnetic Bearing System , 2020, 2020 IEEE 7th International Conference on Industrial Engineering and Applications (ICIEA).

[28]  Herbert Werner,et al.  Efficient Nonlinear Model Predictive Control via quasi-LPV representation , 2016, 2016 IEEE 55th Conference on Decision and Control (CDC).

[29]  Jan Kumbernuss,et al.  A novel magnetic levitated bearing system for Vertical Axis Wind Turbines (VAWT) , 2012 .

[30]  Alessandro Costabeber,et al.  Active Magnetic Bearing system design featuring a predictive current control , 2016, IECON 2016 - 42nd Annual Conference of the IEEE Industrial Electronics Society.

[31]  Abdelfatah M. Mohamed,et al.  Imbalance compensation and automation balancing in magnetic bearing systems using the Q-parameterization theory , 1995, IEEE Trans. Control. Syst. Technol..

[32]  Liuping Wang,et al.  Continuous Time Model Predictive Control for a Magnetic Bearing System , 2007 .

[33]  Peter-Klaus Budig Magnetic bearings and some new applications , 2010, The XIX International Conference on Electrical Machines - ICEM 2010.

[34]  J. Lofberg,et al.  YALMIP : a toolbox for modeling and optimization in MATLAB , 2004, 2004 IEEE International Conference on Robotics and Automation (IEEE Cat. No.04CH37508).

[35]  G. van Schoor,et al.  Model Predictive Control of an Active Magnetic Bearing Suspended Flywheel Energy Storage System , 2015 .

[36]  Wilson J. Rugh,et al.  Research on gain scheduling , 2000, Autom..