DOI
10.34229/KCA2522-9664.25.3.16
UDC 621.396
IIMPROVEMENT OF ARCHITECTURES AND SYSTEM CHARACTERISTICS
OF INTERACTIVE DISTRIBUTED COMPUTER SYSTEMS
Abstract. The functional shortcomings of the architectures of interactive distributed computer systems (IDCS) are analyzed and identified. The algorithms of data formation and processing based on orthogonal functions that generate non-positional number systems are investigated. The star-trunk and star-ring architectures of the IDCS with a high level of parallelization of data exchange processes are developed. The structures of special processors for analog-digital and statistical data processing at the lower levels of the IDCS are developed. The microelectronic structures of analog-to-digital converters (ADC) of the unfolding type with output multifunctional codes in the Rademacher–Christensen and Haar–Christensen bases are implemented.
Keywords: bases of orthogonal functions, number systems, special-purpose processors, interactive computer systems.
full text
REFERENCES
- 1. Melnyk V., Melnyk A., Rahma M. Efficient OAM-based programmable hardware accelerator architecture. 2024 14th International Conference on Advanced Computer Information Technologies (ACIT). Ceske Budejovice, Czech Republic, 2024. P. 683–687. https://www.doi.org/ 10.1109/.
- 2. Miroshnyk M., Koroleva Y., Demenkova S., Shafranskyi A. Models for diagnosing interactive computer networks at the structural and logical level. Bulletin of the National Technical University “KhPI”. A series of “Information and Modeling”. 2024. Vol. 1, N 1–2 (11–12). P. 96–104. https://doi.org/10.20998/.
- 3. Miroshnyk M., Shkil O., Rakhlis D., Miroshnyk A., Loboyhenko D. Constructing tests methods for the interactive computer networks at the structural-logical level. Bulletin of the National Technical University. “KhPI” A series of “Information and Modeling”. 2023. Vol. 1, N 1–2 (9–10). P. 81–90. https://www.doi.org/10.20998/.
- 4. Zhou J. Deep learning-driven distributed communication systems for cluster online educational platform considering human–computer interaction. International Journal of Communication Systems. 2021. Vol. 35. https://www.doi.org/10.1002/.
- 5. Amir Abiri Jahromi, Ankur Srivastava, Astha Chawla, et al. Cyber-physical interdependence for power system operation and control (TR119). Technical Report PES-TR119. IEEE Power & Energy Society, December 2023. https://www.doi.org/10.17023/.
- 6. Blessing N.J. Cyber-physical systems: Integrating computing with physical processes. Research Output Journal of Engineering and Scientific Research. 2024. Vol. 3, N 2. P. 49–52. https://rojournals.org/wp-content/.
- 7. Pushpakumar R., Sanjaya K., Rathika S., Alawadi A., Makhzuna K., Venkatesh S., Rajalakshmi B. Human-computer interaction: Enhancing user experience in interactive systems. E3S Web of Conferences. 2023. Vol. 399 (3). Article Number 04037. https://www.doi.org/10.1051/.
- 8. Protsyuk G.Ya., Protsyuk V.P., Nikolaychuk Ya.M. Technology of interactive interaction of the operator of computerized control of a multi-parameter object based on the image-cluster model. Scientific Bulletin of Ivano-Frankivsk National Technical University of Oil and Gas. 2021. N 1(50). P. 70–76. https://doi.org/10.31471/.
- 9. Abed Alkhafaji M.J., Kuchuk N., Stanovska I., Artabaiev Y., Nechyporuk O., Voznytsia A., Tupota Y., Samoilenko Y., Nikitin D., Rybitskyi O. The development of a method for increasing the reliability of the assessment of the state of the object. Eastern-European Journal of Enterprise Technologies. 2024. Vol. 5, N 3(131). P. 48–54. https://www.doi.org/ 10.15587/.
- 10. Babak V., Babak S., Zaporozhets A. Tasks for creating the environmental monitoring systems for energy objects. In: Statistical Diagnostics of Electric Power Equipment. Studies in Systems, Decision and Control. Cham: Springer, 2024. Vol. 573. P. 345–386. https://www.doi.org/ 10.1007/.
- 11. Chandalwar K.R., Barde N.A., Pureddi S.S., Uike T., Yadgiri N., Dumbere M. Water quality monitoring system based on IoT. International Journal of Advanced Research in Science, Communication and Technology. 2024. Vol. 4, N 3. P. 744–751. https://www.doi.org/10.48175/.
- 12. Denisyuk S.P., Belokha G.S., Gilevich K.M., Cherneschuk I.S. Monitoring of work efficiency in local electric power systems. Proc. Institute of Electrodynamics of the National Academy of Sciences of Ukraine. 2024. Iss. 69. P. 46–55. https://doi.org/10.15407/.
- 13. Skorobogatko S.V., Fesenko G.V., Kharchenko V.S., Yakovlev S.V. Architecture and reliability models of hybrid sensor networks of environmental and emergency monitoring systems. Kibernetyka ta systemnyi analiz. 2024. Vol. 60, N 2. P. 147–159. https://doi.org/10.34229/.
- 14. Pitukh I.R. Method and criteria for assessing the emergence and characteristics of architectures of interactive distributed computer and cyber-physical systems. Physical and mathematical modeling and information technologies. 2021. Iss. 33. P. 115–121. https://doi.org/10.15407/.
- 15. Pitukh I.R. Prospects for improving calculation algorithms and processes for building information logical-statistical models in the Haar–Krestenson basis. Scientific Bulletin of UNFU. 2019. Vol. 29, N 5. P. 151–155. https://doi.org/10.15421/.
- 16. Pitukh I.R., Hrynchyshyn T.M., Davletova A.Ya. Methods and means of building distributed monitoring systems using manipulated optical signals. Scientific Bulletin of UNFU. 2024. Vol. 34, N 7. P 153–160. https://doi.org/10.36930/.
- 17. Multi-level star-ring optical network: pat. 147833 Ukraine: H04B10/112 / T.M. Grinchyshyn, L.M. Nikolaychuk, Ya.V. Petrashchuk, V.M. Griga, I.R. Pitukh. No. u 202007792; appl. 07.12.2020; publ. 16.06.2021. Bull. No. 24. https://iprop-ua.com/inv/.
- 18. Sensor system for measuring snow cover height: pat. 147306 Ukraine: G01W1/14 (2006.01) H04H 60/71 (2008.01) / T.M. Grinchyshyn, Ya.V. Petrashchuk, V.M. Griga, Ya.I. Golynsky, I.R. Pitukh, Ya.M. Nikolaychuk (Ukraine). No. u 202007441; appl. 23.11.2020; publ. 28.04.2021. Bull. No.17. http://dspace.wunu.edu.ua/handle/.
- 19. Nikolaychuk Ya.M., Vozna N.Ya., Pitukh I.R. Design of specialized computer systems [in Ukrainian]. Ternopil: LLC "Terno-graf", 2010. 392 p. http://library.kpi.kharkov.ua/ files/.
- 20. Nikolaychuk Ya.M. Galois field codes [in Ukrainian]. Ternopil: LLC "Terno-graf", 2012. 576 p.
- 21. Vozna N.Ya., Nikolaychuk Ya.M., Volynskyi O.I. Algorithms for solving problems of cryptographic protection of pixels of color images in the Rademacher basis and residual classes. Kibernetika i sistemnyj analiz. 2019. Vol. 55, N 3. P. 149–163. http://www.kibernetika.org/ volumes/2019/.
- 22. Melnyk A. Cyber-physical systems multilayer platform and research framework. Advances in Cyber-Physical Systems. 2016. Vol. 1, N 1. P. 1–6. https://www.doi.org/10.23939/.
- 23. Gorban I.I. Probability Theory and Mathematical Statistics for Scientists and Engineers. Kyiv: IPMMS NASU, 2003. 244 p. http://www.immsp.kiev.ua/perspages/ .
- 24. Vozna N., Nykolaichuk Y., Zastavnyy O., Pikh V. System complexity criteria and synthesis of high-performance multifunctional parallel ADC in Rademacher’s and Haar–Krestenson’s theoretical and numerical bases. 2017 14th International Conference the Experience of Designing and Application of CAD Systems in Microelectronics (CADSM). Lviv, Ukraine, 2017. P. 218–221. https://www.doi.org/10.1109/.
- 25. Device for determining the sample mathematical expectation: pat. 154624 Ukraine: (2023.01) G06F17/00 G06F17/10 (2006.01) / I.R. Pitukh, Ya.M. Nikolaychuk, V.M. Griga, L.M. Nikolaychuk. No. u 202300491; appl. 10.02.2023; publ. 29.11.2023. Bull. No. 48. https://iprop-ua.com/inv/fqzhbtwa/.
- 26. Accumulating binary adder: pat. 150332 Ukraine: G06F7/575 / Ya.M. Nikolaychuk, N.Ya. Vozna, V.M. Griga, I.R. Pitukh, A.Ya. Davletova, L.P. Griga. No. u 202104277; appl. 21.07.2021; publ. 02.02.2022. Bull. No.5. https://iprop-ua.com/inv/myk1d66d/.
