Automated signal synchronisation systems with increased fault tolerance

DOI: https://doi.org/10.15407/akademperiodyka.548.166

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The monograph examines the problems of fault tolerance in power grid and electronic communications synchronisation systems from a modern scientific perspective. It analyses methods and techniques for improving the energy efficiency and fault tolerance of smart technology power grids using synchronised vector measurements. The principles of creation, practical implementation, and technical operation of an intelligent computer-integrated system for multi-channel monitoring of synchronisation signals, digital telecommunications synchronisation equipment with increased fault tolerance, and means of reserving phase synchronisation signals for mobile networks are studied.
The publication is for scientific and engineering, and technical workers, teachers, postgraduates, master’s students, and students of appropriate specialities.

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Chapter 1

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Chapter 2

1. Kalian D., Kazakova N., Kravchenko B., Koval V. Automated system for Monitoring Synchronizing precise time signals at SMART-GRID power plants. T. 1. Projectowanie, badania, i eksploatacja. Wydawnictwo naukowe Akademii technicznohumanistycznej w Bielsku-Bialey. Bielsku-Bialey, 2019. P. 155-160. URL: http://eprints.library.odeku.edu.ua/id/eprint/6544/

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Chapter 3

1. Kalian D., Kazakova N., Kravchenko B., Koval V. Projectowanie, badania, i eksploatacja. In: Automated system for Monitoring Synchronizing precise time signals at SMART-GRID power plants. Bielsku-Bialey: Wydawnictwo naukowe Akademii techniczno-humanistycznej w Bielsku-Bialey, 2019. P. 155-160. URL: http://www.engineerxxi.ath.eu/book/designing-researches-and-exploitation-2019-vol-1/

2. Bregni S. Synchronization of digital telecommunications networks. John Wiley & Sons, Inc., 2002. 315 p. https://doi.org/10.1002/0470845880

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4. G.812, Timing requirements of slave clocks suitable for use as node clocks in synchronization networks [Чинний від 1998-6]. Geneva, Switzerland, June 1998 (Рекомендація ITU-T).

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7. ITU-T Rec. G.823. Controlled slip rate objectives on international digital links.

8. Transmission and multiplexing (TM); Generic requirements for synchronization networks [Chynnyi vid 1996-5]. ETS 300 462-2 1997 (Standart ETSI).

Chapter 4

1. ITU-T Recommendation G.8261.1/Y.1361.1 (02/2012). Packet delay variation network limits applicable to packet-based methods (Frequency synchronization).

2. ITU-T Recommendation G.8275.1/Y.1369.1 (2016). Precision time protocol telecom profile for phase/time synchronization with full timing support from the network.

3. ITU-T Recommendation G.8275.2/Y.1365.2 (2019). Precision time protocol telecom profile for phase/time synchronization with partial timing support from the network.

4. ITU-T Recommendation G.8272/Y.1367 (2012). Timing characteristics of primary reference time clocks.

5. ITU-T Recommendation G.8272.1/Y.1367.1 (2019) Timing characteristics of enhanced primary reference time clocks.

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10. Mills D. L. Computer network time synchronization: the network time protocol. CRC Press, 2006. https://doi.org/10.1201/9781420006155

11. ITU-T Recommendation G.811 (09/97). Timing characteristics of primary reference clock.

12. Vakas V. I., Domin D. A., Manko O. O., Kulinskyi O. O. Evolution of Stability of Synchronization Parameters in Packet Networks. 2017 IEEE First Ukraine Conference on electrical and computer engineering (UKRCON) (May 29 – June 2, 2017): conference proceedings. Kyiv, 2017. P. 886-889. https://doi.org/10.1109/UKRCON.2017.8100375

13. Vakas V. I., Domin D. A., Manko O. O., Kulinskyi O. O. Comparison of synchronization reference signals of primary Atomic Clocks. 2018 IEEE 14th International Conference on Advanced Trends in Radioelecrtronics, Telecommunications and Computer Engineering (TCSET). P. 189-192.