LQR and PID Control Design for a Pneumatic Diaphragm Valve

被引:1
|
作者
Cagnani Conte, Gerson Yuri [1 ]
Marques, Fellipe Garcia [2 ]
Garcia, Claudio [1 ]
机构
[1] Univ Sao Paulo, Sao Paulo, Brazil
[2] Brazilian Navy, Sao Paulo, Brazil
来源
2021 IEEE IFAC INTERNATIONAL CONFERENCE ON AUTOMATION/XXIV CONGRESS OF THE CHILEAN ASSOCIATION OF AUTOMATIC CONTROL (IEEE IFAC ICA - ACCA2021) | 2021年
关键词
Digital control; I/P converter; LQR; PID; pneumatic valve; FRICTION COMPENSATION; STICTION;
D O I
10.1109/ICAACCA51523.2021.9465250
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
This work demonstrates the design and compares the performance of two different digital control techniques for a modeled pneumatic diaphragm valve. The valve model is derived using first-principles modeling, the Karnopp friction model and approximates the UP converter dynamics with a first order filter. The digital PID and LQR controllers were chosen to compensate the valve friction. A proposed contribution is to implement a digital LQR control using the Bryson rule and the Pincer technique to tune the matrices Q and R based on requirements response, maximum deviation of states variables and control effort. The robustness of the LQR controller compared to the PID controller is presented in this paper.
引用
收藏
页数:7
相关论文
共 50 条
  • [21] GA Tuned LQR and PID Controller for Aircraft Pitch Control
    Vishal
    Ohri, Jyoti
    [J]. 2014 IEEE 6TH INDIA INTERNATIONAL CONFERENCE ON POWER ELECTRONICS (IICPE), 2014,
  • [22] LQR and PID Algorithms for Vibration Control of Piezoelectric Composite Plates
    Ezzraimi, Madjid
    Tiberkak, Rachid
    Melbous, Abdelkader
    Rechak, Said
    [J]. MECHANIKA, 2018, 24 (05): : 734 - 740
  • [23] Design of FOPID Controller for Pneumatic Control Valve Based on Improved BBO Algorithm
    Zhu, Min
    Xu, Zihao
    Zang, Zhaoyu
    Dong, Xueping
    [J]. SENSORS, 2022, 22 (17)
  • [24] Asymmetric fuzzy PID control for pneumatic position control system
    Xue, Yang
    Peng, Guang-Zheng
    Fan, Meng
    Wu, Qing-He
    [J]. Journal of Beijing Institute of Technology (English Edition), 2004, 13 (01): : 29 - 33
  • [25] Design of LQR-PID Controller for linearized Magnetic levitation system
    Anurag, Kumar
    Kamlu, Sushma
    [J]. PROCEEDINGS OF THE 2ND INTERNATIONAL CONFERENCE ON INVENTIVE SYSTEMS AND CONTROL (ICISC 2018), 2018, : 444 - 447
  • [26] Beneficially Combining LQR and PID to Control Longitudinal Dynamics of a SmartFly UAV
    Bagheri, Shahriar
    Jafarov, Tural
    Freidovich, Leonid
    Sepehri, Nariman
    [J]. 7TH IEEE ANNUAL INFORMATION TECHNOLOGY, ELECTRONICS & MOBILE COMMUNICATION CONFERENCE IEEE IEMCON-2016, 2016,
  • [27] Performance Evaluation of PID, LQR and MPC for DC Motor Speed Control
    Dani, Siddhesh
    Sonawane, Dayaram
    Ingole, Deepak
    Patil, Sanjaykumar
    [J]. 2017 2ND INTERNATIONAL CONFERENCE FOR CONVERGENCE IN TECHNOLOGY (I2CT), 2017, : 348 - 354
  • [28] Investigation and realisation of PID and LQR control methods in Parrot Mambo minidrone
    Okasha, Mohamed
    Kralev, Jordan K.
    Islam, Maidul
    [J]. INTERNATIONAL JOURNAL OF MODELLING IDENTIFICATION AND CONTROL, 2022, 40 (03) : 249 - 259
  • [29] PID and LQR Control for Two-Wheeled Vehicles with Hand Sensors
    Li, Dian-Rong
    Leu, Yih-Guang
    Wen, Yan-Hou
    [J]. MATERIALS SCIENCE AND PROCESSING, ENVIRONMENTAL ENGINEERING AND INFORMATION TECHNOLOGIES, 2014, 665 : 619 - 622
  • [30] PID plus LQR Attitude Control for Hexarotor MAV in Indoor Environments
    Salim, Nurul Dayana
    Derawi, Dafizal
    Abdullah, Shahrum Shah
    Mazlan, Saiful Amri
    Zamzuri, Hairi
    [J]. 2014 IEEE INTERNATIONAL CONFERENCE ON INDUSTRIAL TECHNOLOGY (ICIT), 2014, : 85 - 90
12345