Intelligent Computer Systems of New Generation and Complex Technology of Their Development, Application and Modernization

The paper considers the trends in the development of artificial intelligence technologies in BSUIR for the last five years, lists the main results obtained during this period both in the field of development of artificial intelligence technologies themselves, and in the field of education in artificial intelligence and realization of interaction between teams of specialists working in this field. The necessity of transition to new-generation intelligent computer systems with a high level of interoperability and creation of an appropriate complex technology for their development, maintenance and operation is substantiated. The problems hindering the active development and implementation of new generation intelligent computer systems are considered. The concept of semantic space as a basis for representation and integration of knowledge in intelligent computer systems of new generation is considered. The principles of implementation of hardware platform for interpretation of information processes in the semantic space – associative semantic computer – are considered.

1. Mikhnevich S. Yu., Tsezhar A. A. (2023) Evolution of the Concept of Interoperability of Open Information Systems. Digital Transformation. 29 (2), 60–66. http://dx.doi.org/10.35596/1729-7648-2023-29-2-60-66 (in Russian).

2. International Conference on Open Semantic Technologies for Intelligent Systems. SpringerLink. Available: https://link.springer.com/conference/ostis (Accessed 28 January 2024).

3. Golenkov V. V., Gulyakina N. A., Shunkevich D. V. (2021) Open Technology of Ontological Design, Production and Operation of Semantically Compatible Hybrid Intelligent Computer Systems. Minsk, Bestprint Publ. (in Russian).

4. Golenkov V. V. (ed.) (2023) Technology of Complex Life Cycle Support of Semantically Compatible Intelligent Computer Systems of New Generation. Minsk, Bestprint Publ. (in Russian).

5. Palagin A. V. (2013) Problems of Transdisciplinarity and the Role of Informatics. Cybernetics and System Analysis. (5), 3–13 (in Russian).

6. Barinov I. I., Borgest N. M., Borovik S. Y., Granichin O. N., Grachev S. P., Gromyko Y. V., et al. (2021) Development Strategy Formation of the Committee on Artificial Intelligence in the Scientific and Educational Center “Engineering of the Future”. Ontology of Designing. 11 (3), 260–293. DOI: 10.18287/2223-9537-2021-11-3-260-293 (in Russian).

7. Golenkov V. V., Gulyakina N. A. (2004) Graphodynamic Associative Models and Means of Parallel Information Processing in Artificial Intelligence Systems. Doklady BGUIR. (1), 92–101 (in Russian).

8. Golenkov V. V., Gulyakina N. A., Davydenko I. T., Shunkevich D. V. (2019) Semantic Technologies for Designing Intelligent Systems and Semantic Associative Computers. Doklady BGUIR. (3), 42–50 (in Russian).

9. Zagorskiy A. (2022) Principles for Implementing the Ecosystem of Next-Generation Intelligent Computer Systems. Open Semantic Technologies for Intelligent Systems (OSTIS-2022): Collection of Scientific Papers. (6), 347–356. Minsk, Bestprint Publ.

10. Pospelov D. A. (ed.) (1990) Artificial Intelligence. Reference Book. In 3 Books. Book 2: Models and Methods. Moscow, Radio and Sviaz Publ. (in Russian).

11. Sowa J. F. (2000) Knowledge Representation: Logical, Philosophical, and Computational Foundations. New York, Brooks/Cole.

12. Martynov V. V. (2009) In the Center of Human Consciousness. Minsk, Belarusian State University (in Russian).

13. Ivashenko V. (2022) General-Purpose Semantic Representation Language and Semantic Space. Open Semantic Technologies for Intelligent Systems (OSTIS-2022): Collection of Scientific Papers. (6), 41–64. Minsk, Bestprint Publ.

14. Ivashenko V. (2023) Semantic Space Integration of Logical Knowledge Representation and Knowledge Processing. Open Semantic Technologies for Intelligent Systems (OSTIS): Collection of Scientific Papers. (7), 95–114. Minsk, Bestprint Publ.

15. Ivashenko V. P. (2017) Ontological Modeling of Event-Based Causal Relationships. Information Technologies and Systems – 2017 (ITS-2017), Proceedings of the International Scientific Conference, Minsk, Oct. 25, 2017. 138–139. Minsk, Belarusian State University of Informatics and Radioelectronics (in Russian).

16. Ivashenko V. P. (2020) Models of Problem Solving in Intellectual Systems. In 2 Parts. Part 1: Formal Models of Information Processing and Parallel Models of Problem Solving. Minsk, Belarusian State University of Informatics and Radioelectronics (in Russian).

17. Ackermann W. (1937) Die Widerspruchsfreiheit der Mengenlehre. Mathematische Annalen. (114), 305–315.

18. Kanamori A. (2009) Bernays and Set Theory. Bulletin of Symbolic Logic. (15), 43–69.

19. Hatcher A. (2002) Algebraic Topology. Great Britain, Cambridge University Press Publ.

20. Ivashenko V. (2023) Structures and Measures in Knowledge Processing Models. Pattern Recognition and Information Processing (PRIP’2023): Proceedings of the 16th International Conference, Minsk, Oct. 17–19, 2023. 16–21. Minsk, United Institute of Informatics Problems of the National Academy of Sciences of Belarus.

21. Ivashenko V. P. (2017) Ontological Model of Space-Time Relations for Events and Phenomena in the Processing of Knowledge. Bulletin of Brest State Technical University. 107 (5), 13–17 (in Russian).

22. Dragalin A. G. (2003) Constructive Theory of Evidence and Non-Standard Analysis. Moscow, URSS Publ.

23. Conway J. H. (2000) On Numbers and Games, 2 ed. US, CRC Press Publ.

24. Zotov N. (2023) Design Principles, Structure, and Development Prospects of the Software Platform of Ostis-Systems. Open Semantic Technologies for Intelligent Systems: Collection of Scientific Papers. (7), 67–76. Minsk, Bestprint Publ.

25. Sapaty P. S. (2023) The Spatial Grasp Model. Great Britain, Emerald Publishing Limited Publ. DOI: 10.1108/9781804555743.

26. Letichevsky A. A., Letychevskyi O. A., Peschanenko V. S. (2012) Insertion Modeling System. Perspectives of Systems Informatics (PSI-2011). Lecture Notes in Computer Science. 7162. Berlin, Heidelberg Publ. DOI: 10.1007/978-3-642-29709-0_23.