Implementation of Decision-Making Systems Based on a Typical Decisive Element

As large amounts of data are received and accumulated, the need to create automated and automatic decision-making systems for a wide variety of tasks becomes more and more urgent. In the technical field, one of them is technical diagnostics, and in medicine, diagnostics of the human condition. Currently, dozens of computer systems for continuous vibration control and monitoring of complex rotary-type units are in commercial operation, which form time trends for 14 vibration parameters with a time step of 1–8 s for each control point at the operated facility. The functionality of a universal decision-making module is proposed, the input data of which are the parameters and characteristics of the observed object, with the required resulting output decision.

1. Balitsky F. Ya. et al. (2005) Non-Destructive Testing: a Reference Book. Volume 7. Book 2. Vibrodiagnostics. Moscow, Mashinostroyeniye Publ. (in Russian).

2. Bently D. E., Hatch C. N., Grissom B. (2002) Fundamentals of Rotating Machinery Diagnostics. Canada: Bently Pressurized Bearing Company.

3. Shirman A. R., Soloviev A. B. (1996) Practical Vibration Diagnostics and Monitoring of the State of Mechanical Equipment. Moscow (in Russian).

4. Barkov A. V., Barkova N. A., Azovtsev A. Yu. (2000) Monitoring and Diagnostics of Rotary Machines by Vibration. St. Petersburg, Ed. Center SPbGMTU (in Russian).

5. Osovsky S. (2002) Neural Networks for Information Processing. Per. from Polish by I. D. Rudinsky. Moscow, Finance and Statistics (in Russian).

6. GOST ISO 10816-1-97. Vibration. Monitoring the Condition of Machines Based on the Results of Vibration Measurements on Non-Rotating Parts. Part 1. General Requirements (in Russian).

7. Brancevich P., Miao X., Li Y. (2013) Organization of the Vibration-Based Monitoring and Diagnostics System for Mechanical Complex System. Proceedings of the 20th International Congress on Sound and Vibration. Bangkok, Thailand. July 7-11.

8. Bransevich P. J., Kostyuk S. F., Sobol G. G. (2003) Organization and Algorithms of the System of Vibration Control and Evaluation of the Technical Condition of Turbine Units by Vibration Parameters. Problems of Vibration, Vibration Adjustment, Vibration Monitoring and Diagnostics of Power Station Equipment: Sat. Reports; under the General Editorship of A. V. Salimon. Moscow, VTI (in Russian).

9. Pavlova L. P. (2017) Dominants of the Active Brain. Systemic Psychophysiological Approach to EEG Analysis. St. Petersburg, INFORM-NAVIGATOR (in Russian).

10. Pupkov K. A., Valtsev V. B. (2000) Processes of Regulation and Control in the Brain and Artificial Intelligence Systems. Intelligent Systems: Proceedings of the Fourth International Symposium. Moscow, RUSSAKI. 19-20 (in Russian).

11. Stepanov M. F., Alpatov M. A., Bubnov R. V. (2000) MISS - System for Modeling Intelligent Self-Organizing Automatic Control Systems. Intelligent Systems: Proceedings of the Fourth International Symposium. Moscow, RUSSAKI. 21-22 (in Russian).

12. Maklakov A. G. (2008) General Psychology: Textbook for Universities. St. Petersburg, Piter Publ. (in Russian).

13. Efimova N. S. (2013) Fundamentals of General Psychology: Textbook for Students of Institutions of Secondary Vocational Education. Moscow, INFRA-M (in Russian).

14. Bransevich P. J., Bazylev E. N. (2016) Big Data in Systems of Vibration Control, Monitoring, Diagnostics. Non-Destructive Testing and Diagnostics. (3) (in Russian).

15. Brancevich P., Li Y. (2018) Detection of Vibration Disturbances During the Analysis of Long Realisations of Vibration Signals. 25th International Congress on Sound and Vibration. Hiroshima. Japan. July 8-12.

16. Brancevich P., Li Y. (2022) Model of the Decision-Making System for Assessment of the State of Technical Objects. Proceedings of the 28th International Congress on Sound and Vibration. Singapore - 2022. USA, The International Institute of Acoustics and Vibration.