Title :
Reliability modeling of hard real-time systems
Author :
Kim, H. ; White, A.L. ; Shin, K.G.
Author_Institution :
Dept. of Electr. Eng., Yonsei Univ., Seoul, South Korea
Abstract :
A hard real-time control system, such as a fly-by-wire system, fails catastrophically (e.g., lose stability) if its control input is not updated by its digital controller computer within a certain time limit called the hard deadline. To assess and validate system reliability by using a semi-Markov model that explicitly contains the deadline information, we propose a path-space approach deriving the upper and lower bounds of the probability of system failure. These bounds are derived by using only simple parameters, and they are especially suitable for highly-reliable systems which must recover quickly. Analytical bounds are derived for both exponential and Weibull failure distributions, which have proven effective through numerical examples, while considering three repair strategies: repair-as-good-as-new, repair-as-good-as-old, and repair-better-than-old.
Keywords :
Markov processes; Weibull distribution; computerised control; digital control; exponential distribution; fault tolerant computing; real-time systems; system recovery; Weibull failure distribution; digital controller computer; exponential distribution; fly-by-wire system; hard deadline; hard real-time control system; lower bounds; path-space approach; probability; reliability modeling; repair strategies; semiMarkov model; system recovery; upper bounds; Control systems; Digital control; Electromagnetic measurements; Failure analysis; NASA; Postal services; Real time systems; Reliability; Stability; Timing;
Conference_Titel :
Fault-Tolerant Computing, 1998. Digest of Papers. Twenty-Eighth Annual International Symposium on
Conference_Location :
Munich, Germany
Print_ISBN :
0-8186-8470-4
DOI :
10.1109/FTCS.1998.689481
