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

Slides:

Advertisements

Similar presentations

9.11. FLUX OBSERVERS FOR DIRECT VECTOR CONTROL WITH MOTION SENSORS

Advertisements

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.

T. YOSHIDA, J. OYAMA, T. HIGUCHI, T. ABE and T. HIRAYAMA Department of Electrical and Electronic Engineering, Nagasaki University, Japan ON THE CHARACTERISTICS.

MSP430 Motor Controller Applications

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

ECE Electric Drives Topic 13: Vector Control of AC Induction

DIGITAL CONTROL STRATEGY FOR FOUR QUADRANT OPERATION OF THREE PHASE BLDC MOTOR WITH LOAD VARIATIONS C. Sheeba Joice, S. R. Paranjothi,and V.Jaeahar Seenthil.

PMSM Control Strategy Reference:

ELECTRIC DRIVES Ion Boldea S.A.Nasar 1998 Electric Drives.

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

IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS, VOL. 57, NO

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

Vector Control of Induction Machines

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

A Position Detection Strategy for Sensorless Surface Mounted Permanent Magnet Motors at Low Speed Using Transient Finite-Element Analysis Zhao Wang, Shuangxia.

Student: Dueh-Ching Lin Adviser: Ming-Shyan Wang Date : 20th-Dec-2009

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

Department of Electrical Engineering Southern Taiwan University

Sensorless Control of the BLDC Motors From Near-Zero to High Speeds

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.

1 An FPGA-Based Novel Digital PWM Control Scheme for BLDC Motor Drives 學生 : 林哲偉學號 :M 指導教授 : 龔應時 IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS, VOL.

Closed-loop Control of DC Drives with Controlled Rectifier

Department of Electrical Engineering, Southern Taiwan University Practical sensorless control for inverter-fed BDCM compressors Student: Chien-Chih Huang.

Dual Winding Method of a BLDC Motor for Large Starting Torque and High Speed IEEE TRANSACTIONS ON MAGNETICS, VOL. 41, NO. 10, OCTOBER 2005 G. H. Jang and.

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

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 current ripple reduction of a high-speed miniature brushless direct current motor.

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.

A New Cost Effective Sensorless Commutation Method for Brushless DC Motors Without Phase Shift Circuit and Neutral Voltage 南台科大電機系 Adviser : Ying-Shieh.

Department of Electrical Engineering Southern Taiwan University of Science and Technology Robot and Servo Drive Lab. 2015/11/20 Simple position sensorless.

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

An Accurate Automatic Phase Advance Adjustment of Brushless DC Motor

Student: Tai-Rong Lai PPT製作率:100% Professor: Ming-Shyan Wang

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

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

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

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.

Professor : Ming – Shyan Wang Department of Electrical Engineering Southern Taiwan University Thesis progress report Sensorless Operation of PMSM Using.

Page 1 國立交通大學電力電子晶片設計與 DSP 控制實驗室 Power Electronics IC Design & DSP Control Lab., NCTU, Taiwan 年 10 月 13 日賴逸軒賴逸.

Department of Electrical Engineering Southern Taiwan University of Science and Technology Robot and Servo Drive Lab. 2016/2/10 Novel PWM Technique Without.

Student: yi-sin Tang Adviser: Ming-Shyan Wang Date :

Disturbance rejection control method

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

Department of Electrical Engineering Southern Taiwan University of Science and Technology Robot and Servo Drive Lab. 2016/2/21 A Novel Rotor Configuration.

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.

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 Initial Rotor Position Estimation for Sensorless Brushless DC Drives Student: G-E Lin.

Department of Electrical Engineering Southern Taiwan University Robot and Servo Drive Lab. 2016/6/13 Design of a Synchronous Reluctance Motor Drive T.

CNC FEED DRIVES Akhil Krishnan G M.Tech 1. CONTENTS 1.Introduction 2.Requirements of CNC feed drives 3.Servo motor 3.1 Servo drive control 3.2 Components.

CNC FEED DRIVES.

Introduction to Motors, servos and steppers

Torque Ripple Reduction in BLDC Torque Motor With Nonideal Back EMF

An FPGA Implementation of a Brushless DC Motor Speed Controller

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

ELECTRONIC & TELECOMMUNICATION DEPARTMENT.

Study on maximum torque generation for sensorless controlled brushless DC motor with trapezoidal back EMF.

Six-Step Operation of PMSM With Instantaneous Current Control

Improved Speed Estimation in Sensorless PM Brushless AC Drives

IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS, VOL. 57, NO

Adviser：Ming-Shyan Wang Student：Hung-Lin Huang

Synchronous Motors and Generators

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.

EEM476 Power Electronics II

Presentation transcript:

Professor: Ming-Shyan Wang Student: CIH-HUEI SHIH Sinusoidal Current Drive System of Permanent Magnet Synchronous Motor with Low Resolution Position Sensor Shigeo Morimoto, Masayulu Sanada, Yoji Takeda Osaka Prefecture University 1-1 Gakuen-cho, Sakai, Osaka 593 JAPAN Professor: Ming-Shyan Wang Student: CIH-HUEI SHIH 2018/9/12

Robot and Servo Drive Lab. Outline 1.Abstract 2.Introduction 3.PM Motor Drive System 4.Principle of Position Estimation 5.Error of Estimated Position 6.Experimental results 7.Conclusions 8.References 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. Abstract The high performance drives of the sinusoidal back-EMF type permanent magnet synchronous motor can be achieved by the current vector control, where the sinusoidal currents flow according to the rotor position and the current phase is suitably controlled according to the operating condition. In such high performance drive system, a high resolution position sensor is desired. In this paper, a sinusoidal current drive system with a low resolution position sensor is proposed. The steady-state and transient characteristics are examined by the several experiments, then it is confirmed that the sinusoidal current drive and the high performance current vector control can be achieved by the proposed drive system. 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. Introduction This paper proposes a sinusoidal current drive system of the sinusoidal-wave PM motor using a low resolution position sensor, which has accuracy of only 60 electrical degrees. The proposed system will have advantage of the low-cost and the simple composition compared with the drive system with a high resolution sensor and the problems included in the sensorless system will be solved. The high resolution position information, which has enough resolution to produce the sinusoidal current commands and achieve a high-performance current vector control, is obtained by the proposed position estimating circuit. 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. PM Motor Drive System The commanded value of an amplitude of phase current The phase shifting angle are generated from the current vector controller. The electrical angle is calculated as = + by the digital adder. (1) 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. PM Motor Drive System 2018/9/12 Robot and Servo Drive Lab.

Principle of Position Estimation Fig. 3 shows the block diagram of the proposed position estimating circuit, which consists of all digital ICs. Fig. 4 shows the time chart of the signals in Fig. 3. The signals M and represent the signals from the low resolution position sensor. Fig. 3 Block diagram of the proposed position estimating circuit 2018/9/12 Robot and Servo Drive Lab.

Principle of Position Estimation Fig. 4 Time chart of the signals in Fig. 3. 2018/9/12 Robot and Servo Drive Lab.

Error of Estimated Position The estimated position may agree with the actual position if the motor speed is constant, where remains constant But, the error between and exists in accelerating or decelerating operation ( for example, in acceleration). The estimated position error can be derived as follows (see Fig. 5). Fig.5 Relationship between speed and position in acceleration 2018/9/12 Robot and Servo Drive Lab.

Error of Estimated Position When the angular acceleration is constant, the motor speed is expressed by (2) Where is an angular velocity of motor at t=0 If the actual rotor position (electrical) is zero at t=0, is given by (3) is a number of pole pairs From(3), and are given by (4) (5) 2018/9/12 Robot and Servo Drive Lab.

Error of Estimated Position As the estimated position , is given based on the average speed of the last period , is expressed by (6) The average speed corresponds to the instantaneous speed at , which is given bv (7) 2018/9/12 Robot and Servo Drive Lab.

Error of Estimated Position From(4),(6)and(7), is given by (8) The estimated position error becomes maximum at in the period of because the estimated position is adjusted to the actual position by the signal Therefore, the maximum value of the estimated position error is given by From (3), (5) and (8), (9) 2018/9/12 Robot and Servo Drive Lab.

Error of Estimated Position 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. Experimental results 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. Experimental results 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. Experimental results 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. Experimental results 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. Experimental results 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. Experimental results 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. Conclusions In this paper, a sinusoidal current drive system of sinusoidal-wave PM motor with low resolution position sensor has been proposed. The high resolution position information is obtained by the position estimating circuit from the low resolution position signal having the accuracy of only 60 electrical degrees. From the experimental results, it has been confirmed that the proposed drive system can achieve the sinusoidal current drive and the high performance current vector control similarly to the general drive system with a high resolution position sensor except for the accelerating and decelerating operation in low speed range. 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. References [l] T. M. Jahns, “Flux-weakening regime operation of an interior permanent-magnet synchronous motor drive,“ ZEEE Trans. Znd. [2] S. Morimoto, K. Hatanaka, Y. Tong, Y. Takeda and T. Hirasa, “Servo Drive System and Control Characteristics of Salient Pole Permanent Magnet Synchronous Motor,“ IEEE Trans. Znd. Appl., vol. 29, pp. 338-343, MarchiApril 1993. [3] S. Morimoto, M. Sanada and Y. Takeda, “Effects and compensation of magnetic saturation in Flux-Weakening Controlled Permanent Magnet Synchronous Motor Drives,” IEEE Trans. Ind. Appl., vol. 30, pp. 1632-1637, Nov./Dec. 1994. [4] S. Ogasawara and H. Akagi, “An Approach to Position Sensorless Drive for Brushless dc Motors,” ZEEE Trans. Ind. Appl., vol. 27, pp. 928-933, Sep./Oct. 1991. [5] R. Wu and G. R. Slemon, “A Permanent Magnet Motor Drive Without a Shaft Sensor,” IEEE Trans. Ind. Appl., vol. 27, pp. 1005-1011, Sep./Oct. 1991. [6] A. B. Kulkarni and M. Ehsani, “A Novel Position Sensor Elimination Technique for the Interior Permanent-Magnet Synchronous Motor Drive,”ZEEE Trans. Ind. Appl., vol. 28, pp. 144-150, Jan./Feb. 1992. [7] N. Matsui and T. Takeshita, “A Novel Starting Method of Sensorless Salient-Pole Brushless Moror,” Proc. I994 IEEE ZASAnn. Meet., pp. 386-392, 1994. [8] S. Kondo, A. Takahashi and T. Nishida, “Armature Current Locus Based Estimation Method of Rotor Position of Permanent Magnet Synchronous Motor without Mechanical Sensor,” Proc. 1995 IEEEZASAnn. Meet., pp. 55-60, 1995. Appl., vol. 23, pp. 681-689, JUly/Aug. 1987. 2018/9/12 Robot and Servo Drive Lab.

Robot and Servo Drive Lab. Thanks for your listening! 2018/9/12 Robot and Servo Drive Lab.