Payload-agnostic Decoupling and Hybrid Vibration Isolation Control for a Maglev Platform with Redundant Actuation

Abstract Payload-specific vibration control may be suitable for a particular task but lacks generality and transferability required for adapting to the various payload. Self-decoupling and robust vibration control are the crucial problem to achieve payload-agnostic vibration control. However, there are problems still unsolved. In this article, we present a maglev vibration isolation platform (MVIP), which aims to attenuate vibration in payload-agnostic task under dynamic environment. Since efforts trying to suppress disturbance will encounter inevitable coupling problems, we analyzed the reasons resulting in it and proposed unique and effective solutions. To achieve payload-agnostic vibration control, we proposed a new control strategy, which is the main contribution of this article. It consists of self-construct radial basis function neural network inversion (SRBFNNI) decoupling scheme and hybrid adaptive feed-forward internal model control (HAFIMC). The former one enables the MVIP creating a self inverse model with little prior knowledge and achieving self-decoupling. For the unique structure of MVIP, the vibration control problem is stated and addressed by the proposed HAFIMC, which utilizes the adaptive part to deal with the periodical disturbance and the internal mode part to deal with the stability.

[1]  Guang Meng,et al.  Microvibration isolation by adaptive feedforward control with asymmetric hysteresis compensation , 2019, Mechanical Systems and Signal Processing.

[2]  Sen M. Kuo,et al.  Active noise control: a tutorial review , 1999, Proc. IEEE.

[3]  Walter M. B. Duval,et al.  THE VIBRATION ENVIRONMENT ON THE INTERNATIONAL SPACE STATION: ITS SIGNIFICANCE TO FLUID-BASED EXPERIMENTS , 2001 .

[4]  Chia-Hsiang Menq,et al.  Active damping and disturbance rejection control of a six-axis magnetic levitation stage. , 2018, The Review of scientific instruments.

[5]  Shubao Shao,et al.  Active-passive hybrid vibration isolation with magnetic negative stiffness isolator based on Maxwell normal stress , 2019, Mechanical Systems and Signal Processing.

[6]  Hengbin Cui,et al.  Design of magnetic bearing control system based on active disturbance rejection theory , 2019 .

[7]  A. Ahadi,et al.  Quasi Steady State Effect of Micro Vibration from Two Space Vehicles on Mixture During Thermodiffusion Experiment , 2012 .

[8]  Jooyoung Park,et al.  Universal Approximation Using Radial-Basis-Function Networks , 1991, Neural Computation.

[9]  T.,et al.  Training Feedforward Networks with the Marquardt Algorithm , 2004 .

[10]  Xingjian Jing,et al.  Recent advances in micro-vibration isolation , 2015 .

[11]  Rongqiang Liu,et al.  Design and control of a novel six-DOF maglev platform for positioning and vibration isolation , 2017, 2017 2nd International Conference on Advanced Robotics and Mechatronics (ICARM).

[12]  Xianzhong Dai,et al.  MIMO system invertibility and decoupling control strategies based on ANN /spl alpha/th-order inversion , 2001 .

[14]  Wanzhong Zhao,et al.  Decoupling control of steering and driving system for in-wheel-motor-drive electric vehicle , 2018 .

[15]  A. Ahadi,et al.  Transient Effect of Micro Vibration from Two Space Vehicles on Mixture During Thermodiffusion Experiment , 2013 .

[16]  Huachun Wu,et al.  Study on mixed H2/H∞ output feedback control of maglev actuator for microgravity vibration isolation system , 2019, Advances in Mechanical Engineering.

[17]  Bo Li,et al.  Vibration control of uncertain multiple launch rocket system using radial basis function neural network , 2018 .

[18]  Lin Li,et al.  The influence of flywheel micro vibration on space camera and vibration suppression , 2018 .

[19]  Iman Tabatabaei Ardekani,et al.  FxLMS-based Active Noise Control : A Quick Review , 2011 .

[20]  Bintang Yang,et al.  Micro-vibration suppressing using electromagnetic absorber and magnetostrictive isolator combined platform , 2020 .

[21]  Rongqiang Liu,et al.  Study of space micro-vibration active isolation platform acceleration measurement , 2015, 2015 IEEE International Conference on Mechatronics and Automation (ICMA).

[22]  G Richardson,et al.  Design and verification of a negative resistance electromagnetic shunt damper for spacecraft micro-vibration , 2017 .

[23]  V. Nguyen,et al.  Two-Phase Lorentz Coils and Linear Halbach Array for Multiaxis Precision-Positioning Stages With Magnetic Levitation , 2017, IEEE/ASME Transactions on Mechatronics.

[24]  Mei-Yung Chen,et al.  Design and Implementation of a New Six-DOF Maglev Positioner With a Fluid Bearing , 2011, IEEE/ASME Transactions on Mechatronics.

[25]  Xiling Xie,et al.  Investigation on active vibration isolation of a Stewart platform with piezoelectric actuators , 2016 .

[26]  Rongqiang Liu,et al.  System integration and control design of a maglev platform for space vibration isolation , 2019, ArXiv.

[27]  Ruey-Jing Lian,et al.  Adaptive Self-Organizing Fuzzy Sliding-Mode Radial Basis-Function Neural-Network Controller for Robotic Systems , 2014, IEEE Transactions on Industrial Electronics.

[28]  B. Moetakef-Imani,et al.  Adaptive inverse control of chatter vibrations in internal turning operations , 2019, Mechanical Systems and Signal Processing.

[29]  Hao Yu,et al.  An Incremental Design of Radial Basis Function Networks , 2014, IEEE Transactions on Neural Networks and Learning Systems.

[30]  Xuebo Yang,et al.  Adaptive NN Backstepping Control Design for a 3-DOF Helicopter: Theory and Experiments , 2020, IEEE Transactions on Industrial Electronics.

[31]  Won-jong Kim,et al.  Nanoscale Motion Control With a Compact Minimum-Actuator Magnetic Levitator , 2005 .

[32]  Wen-Hong Zhu,et al.  On active acceleration control of vibration isolation systems , 2006, 2004 43rd IEEE Conference on Decision and Control (CDC) (IEEE Cat. No.04CH37601).