Vessel heading control systems with switchable regulators

  • Alexander A. Dyda Maritime State University named after Admiral G.I. Nevelskoy
  • Nguyen Van Thanh Maritime State University named after Admiral G.I. Nevelskoy
  • Ksenya N. Chumakova Maritime State University named after Admiral G.I. Nevelskoy

Abstract

The purpose of this work is to study the possibilities of improving the quality of the processes of controlling the movement of the vessel along the course by combining individual standard controllers. Of the known scientific directions devoted to the problem being solved, the closest is the theory of systems with variable structure, in which, due to switching, a unique useful property is achieved, which are not possessed by individual switched structures. The article is devoted to the approach to the construction of the ship course control system, which is based on the principle of switching regulators during the transient process. This makes it possible to improve the quality of control processes in the system by using the features of individual regulators, in particular, the application of the switching principle made it possible to significantly increase the speed of the system in comparison with systems without switching and ensure the desired monotonic nature of the control process. The proposed approach is illustrated based on switchable P-controllers. The results of modeling the developed ship course control system are presented and discussed.

Keywords: ship course control, switchable regulator, control process, mathematical model, computer simulation, monotonic process, switching, system speed, variable structure systems

References

Бесекерский В.А., Попов Е.П. Теория автоматического управления [Текст]/ В.А. Бесекерский, Е.П. Попов. – СПб.: Профессия, 2007. – 752 с.

Вагущенко, Л.Л. Системы автоматического управления движением судна [Текст]/ Л.Л. Вагущенко, Н.Н. Цымбал. – Одесса: Латстар, 2002. – 310 с.

Дёмин С.И., Жуков Е.И., Кубачев Н.А. Управление судном: Учеб. Для вузов. – М.: Транспорт, 1991. – 359 с.

Денисенко В. ПИД – регуляторы: принципы построения и модификации, часть 1 /Денисенко В. // СТА Современные Технологии Автоматизации. – 2006. – №4. – С. 66 – 74

Емельянов С.В. Системы автоматического управления с переменной структурой [Текст]/ С.В. Емельянов. – М.: Наука, 1967. – 336 с.

Изерман Р. Цифровые системы управления. — М.: Мир, 1984. — 541 с.

Ротач В.Я. Теория автоматического управления. — М.: Издательство МЭИ, 2004. — 400 с.

Сирота А.А. Методы и алгоритмы анализа данных и их моделирование в Matlab: учеб. пособие. – СПб.: БХВ - Петербург, 2016. – 384 с.: ил. – (Учебное пособие).

Справочник по теории автоматического управления / Под ред. А.А. Красовского. – М.: Наука, 1987. – 712 с.

Уткин В.И. Скользящие режимы с переменной структурой [Текст]/ В.И. Уткин. – М.: Наука, 1974. – 272 с.

Шарлай Г.Н. Управление морским судном: учбеное пособие/ Г.Н.Шарлай. – Владивосток: Мор. гос. ун-т, 2011. – 543с.

Ang K.H., Chong G., Li Y. PID control system analysis, design, and technology // IEEE Trans. on Control Systems Technology. July 2005. Vol. 13. No. 4. P. 559-576. https://doi.org/10.1109/tcst.2005.847331

Astrom K.J., Hagglund T. Advanced PID control. — ISA (The Instrumentation, Systems, and Automation Society), 2006. — 460 p.

Hodel A.S., Hall C.E. Variable_structure PID control to prevent integrator windup // IEEE Trans. on Industrial Electronics. 2001. Vol. 48. No. 2. P. 442-451. https://doi.org/10.1109/41.915424

Jing_Chung Shen, Huann_Keng Chiang. PID tuning rules for second order systems // Control Conference, 2004 (5th Asian), 20-23 July 2004. Vol. 1. P. 472-477.

Karimi A., Garcia D., Longchamp R. PID controller tuning using Bode’s integrals // IEEE Trans. on Control Systems Technology. Nov. 2003. Vol. 11. No. 6. P. 812-821. https://doi.org/10.1109/tcst.2003.815541

Keel L.H., Rego J.I., Bhattacharyya S.P. A new approach to digital PID controller design // IEEE Trans. on Automatic Control. April 2003. Vol. 48. No. 4. P. 687-692. https://doi.org/10.1109/tac.2003.809768

Li Y., Ang K.H., Chong G.C.Y. Patents, Software, and Hardware for PID control: an overview and analysis of the current art // IEEE Control Systems Magazine. Feb. 2006. P. 42-54. https://doi.org/10.1109/mcs.2006.1580153

Moradi M.H. New techniques for PID controller design // Proceedings of 2003 IEEE Conference on Control Applications (CCA 2003), 23_25 June 2003. Vol. 2. P. 903-908. https://doi.org/10.1109/cca.2003.1223130

Obika M., Yamamoto T. An evolutionary design of robust PID controllers // Mechatronics and Automation, 2005 IEEE International Conference, 29 July _ 1 Aug. 2005. Vol. 1. P. 101-106. https://doi.org/10.1109/icma.2005.1626530

Oviedo J.J.E., Boelen T., van Overschee P. Robust advanced PID control (RaPID): PID tuning based on engineering specifications // IEEE Control Systems Magazine. Feb. 2006. Vol. 26. Issue 1. P. 15-19. https://doi.org/10.1109/mcs.2006.1580148

Silva G.J., Datta A., Bhattacharyya S.P. New results on the synthesis Of PID controllers // IEEE Trans. on Automatic Control. Feb. 2002. Vol. 47. No. 2. P. 241-252. https://doi.org/10.1109/9.983352

Silva G.J., Datta A., Bhattacharyya S.P. On the stability and controller robustness of some popular PID tuning rules // IEEE Trans. on Automatic Control. Sept. 2003. Vol. 48. No. 9. P. 1638-1641. https://doi.org/10.1109/tac.2003.817008

Skoczowski S., Domek S., Pietrusewicz K., Broel_Plater B. A method for improving the robustness of PID control // IEEE Trans. on Industrial Electronics. Dec. 2005. Vol. 52. No. 6. P. 1669_1676. https://doi.org/10.1109/tie.2005.858705

Takao K., Yamamoto T., Hinamoto T. Design of a memory_based selftiming PID controller // 43rd IEEE Conference on Decision and Control (CDC 2004), 14_17 Dec. 2004. Vol. 2. P. 1598-1603. https://doi.org/10.1109/cdc.2004.1430272

Author Biographies

Alexander A. Dyda , Maritime State University named after Admiral G.I. Nevelskoy

Doctor in Engineering Science, Professor of the Department of Automatic and Information Systems, Maritime State University named after Admiral G.I. Nevelskoy, 50-a, st. Verkhneportovaya, Vladivostok, 690059

Nguyen Van Thanh Van Thanh , Maritime State University named after Admiral G.I. Nevelskoy

graduate student, Maritime State University named after Admiral G.I. Nevelskoy, 50-a, st. Verkhneportovaya, Vladivostok, 690059, e-mail: Thanhnv.hvhq@gmail.com

Ksenya N. Chumakova , Maritime State University named after Admiral G.I. Nevelskoy

graduate student, Maritime State University named after Admiral G.I. Nevelskoy, 50-a, st. Verkhneportovaya, Vladivostok, 690059, e-mail:  ksushechka_1991@mail.ru

Published
15-06-2021
How to Cite
Dyda, A. A., Van Thanh, N. V. T., & Chumakova, K. N. (2021). Vessel heading control systems with switchable regulators. Russian Journal of Water Transport, (67), 169-177. https://doi.org/10.37890/jwt.vi67.188
Section
Operation of water transport, navigation and safety of navigation