Design Method for the Magnetic Bearing Control System with Fuzzy-PID Approach 被引量：2

Design Method for the Magnetic Bearing Control System with Fuzzy-PID Approach

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摘要 The five degree freedom magnetic bearing is researched and its structure and working principles are introduced also. Based on the fuzzy control technology, combining fuzzy algorithm and PID control method, identifying the transition process mode of the online system to get the PID parameters＇ self-adjusting, the magnetic beating system＇s Fuzzy-PID nonlinear controller is designed by analyzing the system control demands. The Fuzzy-PID nonlinear controller can deal with the magnetic bearing system＇ s open loop instability and strong nonlinearity, and the approach could improve the system＇s rapidity, adaptability, stability and dynamic characteristics. Comparative analysis and experiments are conducted between linear PID and nonlinear fuzzy- PID control methods, the results show that the fuzzy-PID controller is better, and the five-freedom magnetic bearing＇ s rotary precision experiments are conducted by the fuzzy-PID controller, it satisfies the control rotary precision demands and realizes the hearing＇s steady floating and rotating. The five degree freedom magnetic bearing is researched and its structure and working principles are introduced also. Based on the fuzzy control technology, combining fuzzy algorithm and PID control method, identifying the transition process mode of the online system to get the PID parameters＇ self-adjusting, the magnetic beating system＇s Fuzzy-PID nonlinear controller is designed by analyzing the system control demands. The Fuzzy-PID nonlinear controller can deal with the magnetic bearing system＇ s open loop instability and strong nonlinearity, and the approach could improve the system＇s rapidity, adaptability, stability and dynamic characteristics. Comparative analysis and experiments are conducted between linear PID and nonlinear fuzzy- PID control methods, the results show that the fuzzy-PID controller is better, and the five-freedom magnetic bearing＇ s rotary precision experiments are conducted by the fuzzy-PID controller, it satisfies the control rotary precision demands and realizes the hearing＇s steady floating and rotating.

作者徐春广吕冬明郝娟

机构地区 School of Mechanical and Vehicular Engineering

出处《Journal of Beijing Institute of Technology》 EI CAS 2008年第3期270-273,共4页 北京理工大学学报（英文版）

基金 the"111"Project (B08043)

关键词 magnetic bearing fuzzy design fuzzy-PID control performance experiments magnetic bearing fuzzy design fuzzy-PID control performance experiments

分类号 TP273 [自动化与计算机技术—检测技术与自动化装置]

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参考文献9

1刘德生,尹力明,佘龙华.Fuzzy-PID控制算法在磁悬浮系统中的应用[J].计算机测量与控制,2002,10(6):375-377. 被引量：12
2Habib M K,Inayat-Hussain J I.Fuzzy control scheme for dual-acting magnetic bearing actuator system[].Proceedings of the IEEE Conference on Robotics Automation and Mechatronics.2004
3Hongt S,Langarit R,Joh S J.Fuzzy modeling and control of a nonlinear Magnetic bearing system[].Pro- ceedings of the IEEEInternational Conference on Control Applications.1999
4Tong Shaocheng,Wang Tao,Wang Yanping,et al.De- sign and stability analysis for fuzzy control system[ M][]..2004
5Fukata S,,Shinya M.Control systems and dynamics of cone-shaped magnetic bearings actuated by five electro- magnets[].th International Symposium on Magnetic Bearings: National Aeronautics and Space Administra- tion.1998
6Yu Lie.Systems of active magnetic bearings[ M][]..2003
7Hung J Y.Magnetic bearing control using fuzzy logic[].IEEE Transactions on Industry Applications.1995
8LIU De-sheng,YIN Li-ming,SHE Long-hua (College of Mechano-electronic Engineering and Automation,National University of Defense Technology,Changsha 410073,China).Application of Fuzzy-PID Algorithm in Maglev System[].Computer Automated Measurement & Control.2002
9Shi-Jing huang,Lih-Chang Lin.Fuzzy dynamic output feedback control with adaptive rotor imbalance compensation for magnetic bearing systems[].Transactions on Systems Man and Cybernetics Part B.2004

二级参考文献1

1尹力明,杨泉林.采用永磁悬挂体的磁悬浮系统建模与系统设计方法[J].机车电传动,1999(2):11-13. 被引量：5

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1姚河清,孟庆芹,陈亚政.磁悬浮轴承模糊PID控制器的设计[J].机械,2004,31(8):39-41. 被引量：3
2章志兵,黄挚雄,罗安.中药生产浓缩工段的模糊-智能PID控制研究[J].计算机测量与控制,2005,13(9):935-937. 被引量：2
3陈全,罗安,付青.中药生产过程模糊专家控制[J].计算机测量与控制,2005,13(9):947-950. 被引量：1
4刘志远,蔡肯,白雁力.基于SIMULINK的Fuzzy-PID控制器设计[J].韶关学院学报,2005,26(9):33-35. 被引量：4
5王丽梅,姜国琴.龙门移动式数控机床磁悬浮系统的同步控制[J].组合机床与自动化加工技术,2007(12):35-38. 被引量：1
6谭营,许化龙,曲从善.基于PC/104总线的导弹伺服机构测试系统设计[J].弹箭与制导学报,2008,28(1):86-88.
7邱洪,黄苏丹,曹广忠.基于DSP的磁悬浮球模糊PID数字控制器[J].武汉理工大学学报（信息与管理工程版）,2009,31(6):933-936. 被引量：6
8明正峰,王浩,王璐璐,汶涛,张竟飞.阵列式磁悬浮用电磁铁的定点悬浮模糊控制技术[J].电工技术学报,2011,26(12):7-13. 被引量：4
9邓家朝,何青,孟岳,杨帆,卢正方.基于区间二型模糊PID的磁悬浮控制[J].工业控制计算机,2021,34(4):7-10. 被引量：1
10陈一秀,王永初.一种鲁棒状态控制器的设计及应用[J].计算机测量与控制,2003,11(9):668-670. 被引量：3

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2Zhong Z X, Zhu C S. Vibration of flexible rotor systems with two-degree-of-freedom PID controller of active magnetic bearings [J]. Journal of Vibroengineering, 2013, 15(3): 1302-1310.
3Mansour S E, Kember G C, Dubay R, et al. Online optimization of fuzzy logic-PID of a thermal process [J]. ISATransaction, 2005, 44(4): 305-314.
4王艳敏,冯勇,陆启良.永磁同步电动机的无抖振滑模控制系统设计[J].电机与控制学报,2008,12(5):514-519. 被引量：30
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6张钢,殷庆振,蒋德得,梁世颇.5自由度磁悬浮轴承—转子系统非线性动力学研究[J].机械工程学报,2010,46(20):15-21. 被引量：12
7秦红玲,李志雄,袁松.磁悬浮轴承系统的模糊滑模变结构控制研究[J].计算机仿真,2011,28(4):185-188. 被引量：5
8李明然,贺建军.模糊自适应PID算法在磁悬浮实时控制系统中的应用研究[J].计算机测量与控制,2012,20(10):2690-2692. 被引量：8
9高辉,李怀良,翟长国,陈良亮.电动汽车磁悬浮飞轮电池储能系统设计[J].电力系统自动化,2013,37(1):186-190. 被引量：13
10刘航,徐杜.MATLAB在模糊控制系统设计与仿真中的应用[J].计算机应用研究,2001,18(1):57-59. 被引量：19

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2浦铁成,白晶,浦欣.蚁群算法PID控制器在磁轴承控制系统中的应用[J].北华大学学报（自然科学版）,2007,8(6):562-565. 被引量：1
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