基于遗传算法优化的定子磁链扩展卡尔曼估计方法

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (603 KB)
输出: BibTeX | EndNote (RIS)

摘要定子磁链估计的精度直接关系到异步电机直接转矩控制(DTC)的控制效果, 本文提出了一种基于扩展卡尔曼滤波器(EKF)的定子磁链观测方法, 该方法选取DTC反馈通道中多个主要参数作为状态变量进行联合滤波估计, 为保证EKF算法滤波参数的准确性, 采用遗传算法(GA)对EKF中的系统噪声矩阵和测量噪声矩阵进行了优化处理。通过使用该方法设计的磁链观测器与DTC构成闭环系统进行仿真实验表明, 滤波参数优化后的EKF算法更加有效地提高了磁链估计精度, 从而提高DTC系统的低速控制性能。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	张勇军
	王京
	李华德

关键词 ：磁链估计, 扩展卡尔曼滤波器, 直接转矩控制, 遗传算法

Abstract：The performance of direct torque control (DTC) for induction motor is depended on the stator flux estimation in a large degree. Extended Kalman filter (EKF) is useful to estimate state variables when the measured signal is mixed with noise. A flux linkage flux estimation method for induction motor based on EKF theory is presented in this paper, where, the stator current, stator resistance as well as linkage flux are regarded as the state variables to be estimated by joint filtering. For the sake of improving the accuracy of the filtering, genetic algorithm (GA) is introduced to optimize the noise matrix in EKF. The closed loop system composed by DTC controller and the proposed linkage flux observer with optimized filtering parameter has better estimating accuracy and dynamic low speed performance than ordinary EKF-DTC scheme. The effectiveness is verified by simulation and experimental results.

Key words： Flux estimation extended Kalman filter DTC genetic algorithm

收稿日期: 2008-01-21 出版日期: 2014-02-17

PACS:

TM461

基金资助:国家自然科学基金资助项目(60705017)

作者简介: 张勇军男, 1973年生, 副研究员, 博士研究生, 主要从事新型控制系统理论、交流调速控制理论与应用等领域的研究工作。王京男, 1948年生, 教授, 博士生导师, 主要从事新型控制系统理论与应用, 工业过程自动化, 交流调速理论等领域的研究工作。

引用本文:

张勇军, 王京, 李华德. 基于遗传算法优化的定子磁链扩展卡尔曼估计方法[J]. 电工技术学报, 2009, 24(9): 64-70. Zhang Yongjun, Wang Jing, Li Huade. A Method of the Stator Flux EKF Estimation for Induction Motors Based on Genetic Algorithm Optimizing. Transactions of China Electrotechnical Society, 2009, 24(9): 64-70.

链接本文:

http://dgjsxb.ces-transaction.com/CN/Y2009/V24/I9/64

[1] Deluca A, Ulivi G. Design of exact nonlinear controller for induction motors [J]. IEEE Trans. Automat. Contr., 1989, 34(12): 1304-1307.
[2] Jeon S H, Oh K K, Choi J Y. Flux observer with online tuning of stator and rotor resistances for induction motors[J]. IEEE Trans. on Industrial Electronics, 2002, 49(3):653-664.
[3] Karanayil B, Rahman M F, Grantham C. Stator and rotor resistance observers for induction motor drive using fuzzy logic and artificial neural networks[J]. IEEE Trans. on Energy Conversion, 2005, 20(4):771-780.
[4] Wang K, Chiasson J, Bodson M, et al. A nonlinear least squares approach for identification of the induction motor parameters [J]. IEEE Trans. Automat. Contr., 2005, 50(10). 1622-1628.
[5] Shyu Kuokai, Shang Lijen, Chen Hwangzhi. Flux compensated direct torque control of induction motor drives for low speed operation [J]. IEEE Trans. on Power Electronics, 2004, 19(6):1608-1613.
[6] Nik Rumzi Nik Idris, Adbul Halim Mohamed Yatim. An improved stator flux estimation in steady-state operation for direct torque control of induction machines[J]. IEEE Trans. on Industry Application, 2002, 38(1):110-116.
[7] Hu Jun, Wu Bin. New integration algorithms for estimating motor flux over a wide speed range [J]. IEEE Trans. on Power Electronics, 1998, 13(5): 969-977.
[8] MA X M. Extended Kalman filter for speed sensor-less DTC based on DSP[C]. Proc. of the 4th World Congress on Intelligent Control and Automation, 2002: ll9-122．
[9] Dend Z L, Wang J G．Adaptive extended Kalman filtering for nonlinear systems [J]．Preprints of the 17th JAACE Symposium on Stochastic Theory and its Applications, 1987, l3(5)：375-379．
[10] 邓自立．自校正滤波理论及其应用[M]．哈尔滨：哈尔滨工业大学出版社, 2003.
[11] 徐景硕, 秦永元, 彭蓉．自适应卡尔曼滤波器渐消因子选取方法研究[J]．系统工程与电子技术, 2004, 26(11)：1152-1154．
Xu Jingshuo, Qin Yongyuan, Peng Rong. New method for selecting adaptive Kalman filter [J]. Systems Engineering and Electronics, 2004, 26(11): 1152-1154．
[12] Shi K L, Chan T F, Wong Y K. Speed estimation of an induction motor drive using an optimized extended Kalman filter[J]. IEEE Trans. on Industrial Electronics, 2002, 149(1):124-133.
[13] Chen Junjie, Lu Jun, Huang Weiyi. Non-linearity rectification of sensor systems based on genetic neural networks[J]. Chinese Journal of Scientific Instrument, 2003, 24(2): 201-204.