Abstract
The article is devoted to the impact of recovery strategies and organizing migration of virtual resources on the reliability of fault-tolerant embedded two-machine computing systems. This computer is focused on using cyber-physical systems, which are critical to the continuity of the controlling computational process. Fault tolerance of a computer system is realized in the case of migration of a computational process from a failed computer to a working one. The computational process should not be interrupted after failures. The Markov models of reliability are proposed. Embedded two-machine onboard systems are critical to the continuity of the computational process. Systems include the failure criterion such as loss of continuity of the computational process without the implementation of recovery.
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Bogatyrev, V.A., Aleksankov, S.M., Derkach, A.N. (2020). The Model of Reliability of Dublated Real-Time Computers for Cyber-Physical Systems. In: Kravets, A., Bolshakov, A., Shcherbakov, M. (eds) Cyber-Physical Systems: Industry 4.0 Challenges. Studies in Systems, Decision and Control, vol 260. Springer, Cham. https://doi.org/10.1007/978-3-030-32648-7_2
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