Technological limitations of the Markov method for dependability analysis

Aim. To identify and classify the technical limitations of the Markov method of system dependability analysis, to define their boundaries taking into account the actual feasibility of the method, to show the opportunities of expanding the applicability of the Markov method. The paper examined the limitations associated with the automation of state graph construction and the mathematical solution of the corresponding systems of algebraic and differential equations using software. Methods. An approach is proposed to automatically constructing state graphs of technical systems defined by a structural diagram of dependability, as well as communication networks defined by a structural diagram. The paper examines approaches to reducing the dimension of a state graph that do not reduce the accuracy of dependability indicator calculation. The author also considers ways of reducing the dimensionality of a state graph by means of truncation or merging inoperative states that cause biased calculated dependability values. Results. The actual limits of applicability of the Markov method are shown along with their relevance in the context of modern information technologies. Approaches are shown that expand the applicability of the Markov method for analysing the dependability of large systems. The existing approach to state graph truncation were examined. Approaches to merging inoperative graph states were proposed and investigated (for bias). Conclusion. The approaches discussed in the paper allow extending the applicability of the Markov method of system dependability analysis to systems with a larger number of subsystems.

1. GOST R IEC 61165 2019 (IEC 61165:2006) Risk management. Application of Markov methods. (in Russ.)

2. Viktorova V.S., Stepanyants A.S. [Models and methods for calculating the dependability of technical systems: 2nd edition, revised]. Moscow: LENAND; 2016. (in Russ.)

3. Polovko A.M., Gurov S.V. [Fundamentals of the dependability theory. 2nd ed., revused and enlarged]. St. Petersburg: BHV-Peterburg; 2006. (in Russ.)

4. Ushakov I.A. [Course of systems dependability theory: a study guide for superior education establishments]. Moscow: Drofa; 2008. (in Russ.)

5. Shubinsky I.B. [Structural dependability of information systems. Analysis methods]. Moscow: “Dependability Journal”; 2012. (in Russ.)

6. GOST R IEC 61508-6-2012. Functional safety of electrical/electronic/programmable electronic safety-related systems. Part 6. Guidelines on the application of GOST R IEC 61508-2 and GOST R IEC 61508-3. (in Russ.)

7. Shevchenko D.N. Software for analysis of reliability of SCB-systems by the Markov method. Automation, Communications, Informatics 2018;9:11-13. (in Russ.)

8. Oboskalov V.P. [Structural dependability of electric power systems: a study guide]. Yekaterinburg: UrFU; 2012. (in Russ.)

9. Zelentsov B.P. Defining state-transition diagrams as part of technical state monitoring. Dependability 2022;2:22-29.

10. Kashtanov V.A., Medvedev A.I. [Dependability theory of complex systems. 2nd edition, revised]. Moscow: FIZMATLIT; 2010. (in Russ.)

11. Yunitskiy A.E., Garakh V.A., Tsyrlin M.I. SkyWay string transport for urban passenger transportation. Science and Technology in Transport 2021;3:19-25. (in Russ.)