Shihua Li; Hao Gu Industrial Informatics, IEEE Transactions on Volume: 8, Issue: 4 Digital Object Identifier: 10.1109/TII.2012.2205581 Publication Year:

Slides:

Advertisements

Similar presentations

By ANJU K P Edited By Sarath S Nair M ODELING AND S PEED C ONTROL OF B RUSHLESS DC M OTOR D RIVES BY.

Advertisements

Permanent Magnet Synchronous Motor Drive Using Hybrid PI Speed Controller With Inherent and Non inherent Switching Functions. This paper appears in: Magnetics,

Permanent Magnet Synchronous Motor Drive Using Hybrid PI Speed Controller With Inherent and Noninherent Switching Functions IEEE TRANSACTIONS ON MAGNETICS,

Student: Cheng-Yi Chiang Adviser: Ming-Shyan Wang Date : 31th-Dec-2008

Hybrid Terminal Sliding-Mode Observer Design Method for a Permanent-Magnet Synchronous Motor Control System 教授 : 王明賢學生 : 胡育嘉 IEEE TRANSACTIONS ON INDUSTRIAL.

A Novel Digital Control Technique for Brushless DC Motor Drives

Department of Electrical Engineering Southern Taiwan University Robot and Servo Drive Lab. 2015/5/19 Reduction of Torque Ripple Due to Demagnetization.

1 Research and Development of Machine Drives and Power Conditioning and its Development for Electric Vehicles From 1999 to 2009 Prof. Eric Cheng Department.

Application of Learning Methodologies in Control of Power Electronics Drives J. L. da Silva Neto, L.G. Rolim, W. I. Suemitsu, L. O. A. P. Henriques, P.J.

Department of Electrical Engineering Southern Taiwan University of Science and Technology Robot and Servo Drive Lab. 2015/7/2 Digital Control Strategy.

BIN LI, HOUQIAN LI, LI LI, AND JINLEI ZHANG IEEE TRANSACTIONS ON IMAGE PROCESSING, VOL.23, NO.9, SEPTEMBER

SOUTHERN TAIWAN UNIVERSITY Department of Electrical Engineering DESIGN OF FUZZY PID CONTROLLER FOR BRUSHLESS DC (BLDC)MOTOR Student: Dang Thanh Trung Subject:

Fuzzy Adaptive Internal Model Control Schemes for PMSM Speed-Regulation System Shihua Li; Hao Gu Industrial Informatics, IEEE Transactions on Volume: 8,

EKF-Based PI-/PD-Like Fuzzy-Neural-Network Controller for Brushless Drives Rubaai, A.; Young, P. Industry Applications, IEEE Transactions on Volume: 47.

Department of Electrical Engineering Southern Taiwan University Robot and Servo Drive Lab. 2015/9/9 A Novel Four-Level Converter and Instantaneous Switching.

Student: Tai-Rong Lai Professor: Ming-Shyan Wang

A Shaft Sensorless Control for PMSM Using Direct Neural Network Adaptive Observer Authors: Guo Qingding Luo Ruifu Wang Limei IEEE IECON 22 nd International.

Department of Electrical Engineering Southern Taiwan University Robot and Servo Drive Lab. 2015/9/18 Pulsewidth Modulation Technique for BLDCM Drives to.

班級：控晶四乙老師：王明賢學生：洪嘉偉 Mechanical Sensorless Speed Control of Permanent-Magnet AC Motors Driving an Unknown Load Cristian De Angelo,Guillermo Bossio,Jorge.

SIMULINK/MODELSIM CO-SIMULATION OF FPGA-BASED PI SPEED CONTROL FOR PMSM DRIVE STUDENT: PHAM VAN DUNG ID: MA02B205 ELECTRICAL ENGINEERING DEPARTMENT SOUTHERN.

1 Deadzone Compensation of an XY –Positioning Table Using Fuzzy Logic Adviser : Ying-Shieh Kung Student : Ping-Hung Huang Jun Oh Jang; Industrial Electronics,

Sensorless Sliding-Mode Control of Induction Motors Using Operating Condition Dependent Models 教授：王明賢學生：謝男暉南台科大電機系.

Huixian Liu and Shihua Li, Senior Member, IEEE

Department of Electrical Engineering Southern Taiwan University of Science and Technology Robot and Servo Drive Lab. 2015/10/27 DSP-Based Control of Sensorless.

Motion control 主題 : Observer-Based Speed Tracking Control for Sensorless Permanent Magnet Synchronous Motors With Unknown Load Torque 作者 : Patrizio Tomei.

Department of Electrical Engineering, Southern Taiwan University 1 A Novel Starting Method of the Surface Permanent-Magnet BLDC Motors Without Position.

Department of Electrical Engineering, Southern Taiwan University 1 A novel sensorless control method for brushless DC motor Student: Wei-Ting Yeh Adviser:

A High-Speed Sliding-Mode Observer for the Sensorless Speed Control of a PMSM Hongryel Kim, Jubum Son, and Jangmyung Lee, Senior Member, IEEEIEEE TRANSACTIONS.

Sensorless Control of the Permanent Magnet Synchronous Motor Using Neural Networks 1,2Department of Electrical and Electronic Engineering, Fırat University.

Student: Chien-Chih Huang Teacher: Ming-Shyan Wang Date :

研究生：林易德指導教授 : 龔應時學號： MA Simulink/ModelSim Co-Simulation of Sensorless PMSM Speed Controller 1.

Twelve-Step_Sensorless_Drive_Scheme_for_a_Brushless_DC_Motor 南台科技大學電機工程系來源 : Chao-Min Wang; Shyh-Jier Wang; Shir-Kuan Lin; Hsing-Yu Lin; A Novel Twelve-Step.

Student: Hsin-Feng Tu Professor: Ming-Shyan Wang Date : Dec,29,2010

Introduction to Motion Control

Department of Electrical Engineering Southern Taiwan University of Science and Technology Robot and Servo Drive Lab. 2015/12/6 Professor ： Ming-Shyan Wang.

A System-on-Chip Sensorless Control for a Permanent-Magnet Synchronous Motor Adviser : Ming-Shyan Wang Student :Yu-Ming Liao IEEE TRANSACTIONS ON INDUSTRIAL.

IEEE TRANSACTIONS ON MAGNETICS, VOL. 42, NO. 10, OCTOBER Optimal Commutation of a BLDC Motor by Utilizing the Symmetric Terminal Voltage G. H. Jang.

ECEN 679 Project 1 Topic 22: Fault Location Using Synchronized Phasors Po-Chen Chen Instructor: Dr. M. Kezunovic Mar. 3, 2014.

Design and Implementation of a High-Performance PMLSM Drives Using DSP Chip Student : Le Thi Van Anh Advisor : Ying-Shieh Kung IEEE TRANSACTIONS ON INDUSTRIAL.

Department of Electrical Engineering Southern Taiwan University Robot and Servo Drive Lab. 2015/12/23 Torque Ripple Reduction in BLDC Torque Motor With.

A T ORQUE R IPPLE C OMPENSATION T ECHNIQUE FOR A L OW -C OST B RUSHLESS DC M OTOR D RIVE H. K. Samitha Ransara and Udaya K. Madawala, Senior Member, IEEE.

Pulsating Signal Injection-Based Axis Switching Sensorless Control of Surface-Mounted Permanent- Magnet Motors for Minimal Zero-Current Clamping Effects.

Hybrid Load Forecasting Method With Analysis of Temperature Sensitivities Authors: Kyung-Bin Song, Seong-Kwan Ha, Jung-Wook Park, Dong-Jin Kweon, Kyu-Ho.

Department of Electrical Engineering Southern Taiwan University Robot and Servo Drive Lab. Commutation Control for the Low-Commutation Torque Ripple in.

Department of Electrical Engineering Southern Taiwan University of Science and Technology Robot and Servo Drive Lab. 學生 : 蔡景棠指導教授 : 王明賢 2016/1/17 Compensation.

An Energy-Efficient Motor Drive With Autonomous Power Regenerative Control SystemBased on Cascaded Multilevel Inverters and Segmented Energy Storage 研究生.

© Anti-Swing Control Of Gantry And Tower Cranes Using Fuzzy And Time-Delayed Feedback With Friction Compensation Omar, HM; Nayfeh, AH IOS PRESS,

Disturbance rejection control method

Department of Electrical Engineering Southern Taiwan University Robust Nonlinear Speed Control of PM Synchronous Motor Using Boundary Layer Integral Sliding.

Student: Chien-Chih Huang Teacher: Ming-Shyan Wang Date :

Department of Electrical Engineering Southern Taiwan University NEW Initial Position Detection Technique for Three-Phase Brushless DC Motor without Position.

Department of Electrical Engineering Southern Taiwan University Industry Application of Zero-Speed Sensorless Control Techniques for PM Synchronous Motors.

Department of Electrical Engineering Southern Taiwan University Simple position sensorless starting method for brushless DC motor Student: Po-Jui Hsiao.

Student: Po-Jui Hsiao Adviser: Ming-Shyan Wang Date : 4/12/2011

Department of Electrical Engineering Southern Taiwan University Robot and Servo Drive Lab. 2016/3/11 High-Speed Sliding-Mode Observer for the Sensorless.

A Novel Universal Sensor Concept for Survivable PMSM Drives Yao Da, Student Member, IEEE, Xiaodong Shi, Member, IEEE, and Mahesh Krishnamurthy, Senior.

Department of Electrical Engineering Southern Taiwan University of Science and Technology Robot and Servo Drive Lab. 2016/3/14 Sensorless Control Method.

Department of Electrical Engineering, Southern Taiwan University Initial Rotor Position Estimation for Sensorless Brushless DC Drives Student: G-E Lin.

Han Ho Choi, Member, IEEE, Nga Thi-Tuy Vu, and Jin-Woo Jung IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS, VOL. 59, NO. 8, AUGUST 2012,pp /9/241.

Torque Ripple Reduction in BLDC Torque Motor With Nonideal Back EMF

Adviser: Ming-Shyan Wang Student: Feng-Chi Lin

Six-Step Operation of PMSM With Instantaneous Current Control

Improved Speed Estimation in Sensorless PM Brushless AC Drives

Professor: Ming-Shyan Wang Student: CIH-HUEI SHIH

Date of download: 12/29/2017 Copyright © ASME. All rights reserved.

Advisor：Nortren Tsai Speaker：B.Y. Wu

CONTROL SYSTEM AN INTRODUCTION.

Objective: The main aim of this project is to control the speed of the brush less direct current motor based on the single current sensor is proposed.

Department of Electrical Engineering National Central University

Rich QR Codes With Three-Layer Information Using Hamming Code

Presentation transcript:

Shihua Li; Hao Gu Industrial Informatics, IEEE Transactions on Volume: 8, Issue: 4 Digital Object Identifier: /TII Publication Year: 2012, Page(s): 767 – 779 IEEE JOURNALS & MAGAZINES Student : 鍾子涵

2

 In this paper, the speed regulation problem for permanent magnet synchronous motor (PMSM) system under vector control framework is studied. First, a speed regulation scheme based on standard internal model control (IMC) method is designed. For the speed loop, a standard internal model controller is first designed based on a first-order model of PMSM by analyzing the relationship between reference quadrature axis current and speed. For the two current loops, PI algorithms are employed respectively. Second, considering the disadvantages that the standard IMC method is sensitive to control input saturation and may lead to poor speed tracking and load disturbance rejection performances, a modified IMC scheme is developed based on a two-port IMC method, where a feedback control term is added to form a composite control structure. Third, considering the case of large variations of load inertia, two adaptive IMC schemes with two different adaptive laws are proposed. 3

4

5

6

7

8

9

10

11

12

13

14

15

16

17

18

19

20

21

22

 [1] Y. X. Su, C. H. Zheng, and B. Y. Duan, “Automatic disturbances rejection controller for precise motion control of permanent-magnet synchronous motors,” IEEE Trans. Ind. Electron., vol. 52, no. 3, pp. 814–823, Mar  [2] K. H. Kim and M.-J. Youn, “A nonlinear speed control for a PM synchronous motor using a simple disturbance estimation technique,” IEEE Trans. Ind. Electron., vol. 49, no. 3, pp. 524–535, Mar  [3] I. C. Baik, K.-H. Kim, and M. J. Youn, “Robust nonlinear speed control of PM synchronous motor using boundary layer integral sliding mode control technique,” IEEE Trans. Control Syst. Technol., vol. 8, no. 1, pp. 47–54, Jan  [4] S. H. Li and Z. G. Liu, “Adaptive speed control for permanent magnet synchronous motor systemwith variations of load inertia,” IEEE Trans. Ind. Electron., vol. 56, no. 8, pp. 3050–3059, Aug  [5] Y. A.-R. I. Mohamed, “Design and implementation of a robust current control scheme for a PMSM vector drive with a simple adaptive disturbance observer,” IEEE Trans. Ind. Electron., vol. 54, no. 4, pp.1981–1988, Apr  [6] S. M. Yang and Y. J. Deng, “Observer-based inertia identification for autotuning servo motor drivers,” in Proc. 40th IAS Annu. Meeting, Hong Kong, 2005, pp. 968–972.  [7] H. H. Choi, N. T.-T.Vu, and J.-W. Jung, “Digital implementation of an adaptive speed regulator for a PMSM,” IEEE Trans. Power Electron., vol. 26, no. 1, pp. 3–8, Feb  [8] F. F. M. El-Sousy, “Hybrid H-infinity-based wavelet-neural-network tracking control for permanent-magnet synchronous motor servo drives,” IEEE Trans. Ind. Electron., vol. 57, no. 9, pp. 3157–3166, Sep  [9] T. L. Hsien, Y. Y. Sun, and M. C. Tsai, “ control for a sensorless permanent-magnet synchronous drive,” IEE Proc.-Electr. Power Appl., vol. 144, no. 3, pp. 173–181,  [10] Y. Luo, Y. Q. Chen, H.-S. Ahnc, and Y. G. Pi, “Fractional order robust control for cogging effect compensation in PMSM position servo systems: Stability analysis and experiments,” Contr. Eng. Practice, vol. 18, no. 9, pp. 1022–1036,  [11] K. H. Kim, I. C. Baik, G.-W. Moon, and M.-J. Youn, “A current control for a permanent magnet synchronous motor with a simple disturbance estimation scheme,” IEEE Trans. Control Syst. Technol., vol. 7, no. 5, pp. 630–633, May  [12] S.H.Li, H. X. Liu, and S.H.Ding, “Aspeed control for a PMSMusing finite-time feedback control and disturbance compensation,” Tran. Inst. Measur. Contr., vol. 32, no. 2, pp. 170–187,  [13] P. Cortes, M. P. Kazmierkowski, R. M. Kennel, D. E. Quevedo, and J. Rodriguez, “Predictive control in power electronics and drives,” IEEE Trans. Ind. Electron., vol. 55, no. 12, pp. 4312–4324, Dec  [14] H. X. Liu and S. H. Li, “Speed control for PMSM servo system using predictive functional control and extended state observer,” IEEE Trans. Ind. Electron., vol. 59, no. 2, pp. 1171–1183, Feb  [15] Y. S. Kung and M. H. Tsai, “FPGA-based speed control IC for PMSM drive with adaptive fuzzy control,” IEEE Trans. Power Electron., vol. 22, no. 6, pp. 2476–2486, Dec