Method of identification of dedicated computer networks for computer systems of objects of oil and gas complex

Authors

  • Сергій Миронович Бабчук Ivano-Frankivsk National Technical University of Oil and Gas Karpatska Street, 15, Ivano-Frankivsk city, 76019, Ukraine

DOI:

https://doi.org/10.15587/1729-4061.2013.14764

Keywords:

dedicated computer networks, method, classification, algorithm, oil and gas complex

Abstract

For many years the automation systems used to be constructed on the basis of analogue devices.  However, in the conditions of rapidly growing production of micro processing systems, multiple nodes dedicated computer networks that digitally exchange data emerged as an alternative solution.

Nowadays, the companies of the world use more than hundred different dedicated computer networks.

During modernization period the companies need to choose optimal decisions for specific technological areas. However, at present time, methodological background for effective solution of mentioned problem practically does not exist. 

There has been done research of the existing dedicated computer networks.

We have developed classification of dedicated computer networks that can be used on the objects of oil and gas complex.

Also, there was created selection algorithm of dedicated computer network for computer systems of the objects of oil and gas complex.

We have developed method of identification of dedicated computer networks for computer systems of objects of oil and gas complex. Thus, we have created a methodological background that will assist enterprises in their choice of optimal decisions for specific technological areas.

Author Biography

Сергій Миронович Бабчук, Ivano-Frankivsk National Technical University of Oil and Gas Karpatska Street, 15, Ivano-Frankivsk city, 76019

Associate Professor

Department of Computer Systems and Networks

References

  1. Сахнюк, А. А. Промышленные сети [Текст] / А. А. Сахнюк, А. М. Литвин // Передовые технологии и технические решения. – 2004. – № 2. – С. 6–8.
  2. Satynarayana, S. Performance of H1 Network in Wind Turbine Generator with Foundation Fieldbus [Text] / S. Satynarayana, M. Sailaja // International Journal of Engineering Science and Technology. – 2012. – № 4(7). – P. 27–32.
  3. Shu, Z. Study of Practical DNC System Based on CAN Fieldbus [Text] / Z. Shu // Journal of Dalian Jiaotong University. – 2009. – № 30(1). – P. 9–12.
  4. Swider, Z. The integration of CAN and Modbus protocols in a distributed control system [Text] / Z. Swider, W. Mikluszka, D. Rzonca // PAK. – 2005. – № 1(1). – P. 21–24.
  5. Chauhan, A. A. Designing of MODBUS for Continues Process Control [Text] / A. A. Chauhan, A. R. Mahajan // International Journal of Advanced Engineering Science and Technology. – 2011. – № 3(1). – P. 24–28.
  6. Vaijapurkar, S. S. Implementation Strategy for Optical Fiber Modbus-TCP Based Nuclear Radiation Detection Instrument for Nuclear Emergency [Text] / S. S. Vaijapurkar, S. M. Kate // International Journal of Engineering Trends and Technology. – 2012. – № 3(3). – P. 462–465.
  7. Peng, J. Application of IEEE 802.1P in Industrial Ethernet [Text] / J. Peng, Z. Shu, Q. Ying // Journal of Nanchang University Engineering & Technology. – 2009. – № 31(1). – P. 49–52.
  8. Кругляк, К. В. Промышленные сети: цели и средства [Текст] / К. В. Кругляк // Современные технологии автоматизации. – 2002. – № 4.– С. 6–17.
  9. Сахнюк, А. А. Межсетевое взаимодействие в промышленных сетях [Текст] / А. А. Сахнюк // Передовые технологии и технические решения. – 2004. – № 3. – С. 6–11.
  10. Семенцов, Г. Н. Автоматизація процесу буріння свердловин [Текст]: навчальний посібник / Г. Н. Семенцов – Івано-Франківськ: ІФДТУНГ, 1999. – 300 с.
  11. Бабчук, С. М. Класифікація промислових комп’ютерних мереж [Текст] / С. М. Бабчук // Восточно-европейский журнал передовых технологий. – 2009. – № 4/2 (40). – С. 14-17.
  12. Sakhniuk, A. (2004). Industrial networks. Advanced Technologies and Technical Solutions, 2, 6-8.
  13. Satynarayana, S., Sailaja, M. (2012). Performance of H1 network ing wind turbine generator with Foundation Fieldbus. International Journal of Engineering Science and Technology, 4, 27-32.
  14. Zhu, S. (2009). Study of practical DNC system based on CAN Fieldbus. Journal of Dalian Jiaotong University, 30, 9-12.
  15. Swider, Z., Mikluszka, W., & Rzonca, D. (2005). The integration of CAN and Modbus protocols in a distributed
  16. control system. PAK, 1, 21-24.
  17. Chauhan, A., Mahajan, A. (2011). Designing of Modbus for continues process control. International Journal of Advanced Engineering Science and Technology, 3, 24-28.
  18. Vaijapurkar, S., Kate, S. (2012). Implementation strategy for optical fiber Modbus-TCP based nuclear radiation detection instrument for nuclear emergency. International Journal of Engineering Trends and Technology, 3, 462-465.
  19. Peng, J., Shu, Z., & Ying Q. (2009). Application of IEEE 802.1P in Industrial Ethernet. Journal of Nanchang University Engineering & Technology, 31, 49-52.
  20. Kruhliak, K. (2002). Industrial networks: objectives and means. Modern technologies of automation, 4, 6-17.
  21. Sakhniuk, A. (2004). Internetwork interrelation in industrial networks. Advanced technologies and technical solutions, 3, 6-11.
  22. Sementsov, H. (1999). Automation of the process of well drilling: study guide. IFSTUOG, 300 P.
  23. Babchuk, S. (2009). Classification of industrial computer networks. Eastern-European Journal of Enterprise Technologies, 4, 14-17.

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Published

2013-06-19

How to Cite

Бабчук, С. М. (2013). Method of identification of dedicated computer networks for computer systems of objects of oil and gas complex. Eastern-European Journal of Enterprise Technologies, 3(4(63), 48–51. https://doi.org/10.15587/1729-4061.2013.14764

Issue

Vol. 3 No. 4(63) (2013): Mathematics and cybernetics - fundamental ans applied aspects

Section

Mathematics and Cybernetics - applied aspects

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Copyright (c) 2014 Сергій Миронович Бабчук

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