LQR optimized BP neural network PI controller for speed control of brushless DC motor

被引:12
作者
Wang, Tingting [1 ]
Wang, Hongzhi [1 ,2 ]
Hu, Huangshui [3 ]
Wang, Chuhang [4 ]
机构
[1] Changchun Univ Technol, Coll Mechatron Engn, Changchun, Peoples R China
[2] Changchun Univ Technol, Coll Comp Sci & Engn, Changchun, Peoples R China
[3] Jilin Univ Architecture & Technol, Coll Comp Sci & Engn, 1111 Xuejian Rd, Changchun 130114, Peoples R China
[4] Changchun Normal Univ, Coll Comp Sci & Technol, Changchun, Peoples R China
来源
ADVANCES IN MECHANICAL ENGINEERING | 2020年 / 12卷 / 10期
关键词
Linear quadratic regulator; back propagation neural network; PI; BLDC motor; speed control; CONTROL STRATEGY; BLDC MOTOR; DESIGN; ALGORITHM; HYBRID; SYSTEM;
D O I
10.1177/1687814020968980
中图分类号
O414.1 [热力学];
学科分类号
摘要
This paper proposes a linear quadratic regulator (LQR) optimized back propagation neural network (BPNN) PI controller called LN-PI for the speed control of brushless direct current (BLDC) motor. The controller adopts BPNN to adjust the gain K-P and K-I of PI, which improves the dynamic characteristics and robustness of the controller. Moreover, LQR is adopted to optimize the output of BPNN so as to make it close to the target PI gains. Finally, the optimized control output is inputted into the BLDC motor system to achieve speed control. The performance analysis of the proposed controller is presented to compare with traditional PI controller, neural network PI controller and LQR optimized PI controller under MATLAB/Simulink, the results shows that the proposed controller effectively improves the response speed, reduces the steady-state error and enhances the anti-interference ability.
引用
收藏
页数:13
相关论文
共 32 条
[1]  
Afrasiabi N, 2013, GLOBAL J SCI ENG TEC, V11, P45
[2]   A hybrid of sliding mode control and fuzzy logic control using a fuzzy supervisory switched system for DC motor speed control [J].
Ahmed, Husain ;
Rajoriya, Abha .
TURKISH JOURNAL OF ELECTRICAL ENGINEERING AND COMPUTER SCIENCES, 2017, 25 (03) :1993-2004
[3]   Reactive power control using dynamic Particle Swarm Optimization for real power loss minimization [J].
Badar, Altaf Q. H. ;
Umre, B. S. ;
Junghare, A. S. .
INTERNATIONAL JOURNAL OF ELECTRICAL POWER & ENERGY SYSTEMS, 2012, 41 (01) :133-136
[4]   Braking Torque Control Strategy for Brushless DC Motor With a Noninductive Hybrid Energy Storage Topology [J].
Cao, Yanfei ;
Shi, Tingna ;
Yan, Yan ;
Li, Xinmin ;
Xia, Changliang .
IEEE TRANSACTIONS ON POWER ELECTRONICS, 2020, 35 (08) :8417-8428
[5]   Neural Network-Based Real Time PID Gain Update Algorithm for Contour Error Reduction [J].
Cho, Chang Nho ;
Song, Young Hun ;
Lee, Chang-Hyuk ;
Kim, Hong Ju .
INTERNATIONAL JOURNAL OF PRECISION ENGINEERING AND MANUFACTURING, 2018, 19 (11) :1619-1625
[6]   LQR based improved discrete PID controller design via optimum selection of weighting matrices using fractional order integral performance index [J].
Das, Saptarshi ;
Pan, Indranil ;
Halder, Kaushik ;
Das, Shantanu ;
Gupta, Amitava .
APPLIED MATHEMATICAL MODELLING, 2013, 37 (06) :4253-4268
[7]   Off-line tuning of a PI speed controller for a permanent magnet brushless DC motor using DSP [J].
Demirtas, Metin .
ENERGY CONVERSION AND MANAGEMENT, 2011, 52 (01) :264-273
[8]   Direct Self-Control for BLDC Motor Drives Based on Three-Dimensional Coordinate System [J].
Gao, Jin ;
Hu, Yuwen .
IEEE TRANSACTIONS ON INDUSTRIAL ELECTRONICS, 2010, 57 (08) :2836-2844
[9]   Dynamic Modeling and Neural Network Self-tuning PID Control Design for a Linear Motor Driving Platform [J].
Hsieh, Sheng-Ping ;
Hwang, Thong-Shing .
IEEJ TRANSACTIONS ON ELECTRICAL AND ELECTRONIC ENGINEERING, 2010, 5 (06) :701-707
[10]   Speed control of brushless direct current motor using a genetic algorithm-optimized fuzzy proportional integral differential controller [J].
Hu, Huangshui ;
Wang, Tingting ;
Zhao, Siyuan ;
Wang, Chuhang .
ADVANCES IN MECHANICAL ENGINEERING, 2019, 11 (11)
1234