PLC-based discrete fractional-order control design for an industrial-oriented water tank volume system with input delay-Reference-Cited by-同舟云学术

PLC-based discrete fractional-order control design for an industrial-oriented water tank volume system with input delay

Published:2018-08-01 Issue:4 Volume:21 Page:1005-1026
ISSN:1314-2224
Container-title:Fractional Calculus and Applied Analysis
language:en
Short-container-title:

Author:

Mystkowski Arkadiusz¹,Zolotas Argyrios²

Affiliation:

1. Bialystok University of Technology Department of Automatic Control and Robotics Bialystok , Bialystok , Poland

2. School of Engineering , College of Science University of Lincoln , Lincoln , LN6 7TS , UK

Abstract

Abstract We present PLC-based fractional-order controller design for an industrial-oriented water tank volume control application. The system comprises input delay which is a typified characteristic in such industrial process control applications. The particular contribution of this work is on discrete fractional-order PID implementation via PLC and its application to the aforementioned realistic water tank test bed. Stability and robustness properties of fractional-order discrete PID feedback-loops for different approximation methods and orders are also shown. Fractional-order controllers are obtained for a variety of stability margin choices, and benefits of the non-integer-order controllers compared to the integer-order PID control are illustrated via simulation and experimental runs on a realistic test-bed.

Publisher

Walter de Gruyter GmbH

Subject

Applied Mathematics,Analysis

Link

https://www.degruyter.com/document/doi/10.1515/fca-2018-0055/pdf

Reference22 articles.

1. O.P. Agrawal, Generalized multiparameters fractional variational calculus. Intl. J. of Diff. Eq. 2012 (2012), Article ID 521750; 10.1155/2012/521750.

2. K.J. Äström, Limitations on control system performance. European J. of Contr. 6, No 1 (2000), 2–20.

3. B. Bandyopadhyay, S. Kamal, Stabilization and Control of Fractional Order Systems: A Sliding Mode Approach. Lect. Notes in Electr. Eng., Springer Intl. Publ. (2015).

4. N.R.O. Bastos, R.A.C. Ferreira, D.F.M. Torres, Necessary optimality conditions for fractional difference problems of the calculus of variations. Discr. & Cont. Dyn. Sys. 29, No 2 (2011), 417–437.

5. D.W. Brzezinski, P. Ostalczyk, About accuracy increase of fractional order derivative and integral computations by applying the Grunwald-Letnikov formula. Comm. Nonlin. Sci. Numer. Sim. 40 (2016), 151–162.

Cited by 11 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Design of PIDDα Controller for Robust Performance of Process Plants;Algorithms;2023-09-11

2. Intelligent Conversion Method from Function Block Diagram to Instruction List Based on AOV Diagram and Series-Parallel Merge Algorithm;2023 42nd Chinese Control Conference (CCC);2023-07-24

3. Using Sine Function-Based Nonlinear Feedback to Control Water Tank Level;Energies;2021-11-13

4. Robust Controller Decorated by Nonlinear S Function and Its Application to Water Tank;Applied System Innovation;2021-09-07

5. Robust fractional-order perfect control for non-full rank plants described in the Grünwald-Letnikov IMC framework;Fractional Calculus and Applied Analysis;2021-08-01