Optimal design of systems with standby dependencies.
L.M. Ridley
J.D. Andrews
2134/3677
https://repository.lboro.ac.uk/articles/Optimal_design_of_systems_with_standby_dependencies_/9228986
The technique of fault tree analysis is commonly used to assess the probability of failure of industrial systems. The
fault tree represents the failure logic of the system in an inverted tree structure and has the advantage that it provides
very good documentation of the way that the failure logic was developed. During the analysis of a fault tree the
component failures or basic events are assumed to occur independently. When this condition is not satisfied,
as in the case of standby systems for example, alternative approaches such as Markov methods can be used.
Constructing the state transition diagram required for aMarkov model is not such an intuitive process for engineers
as fault tree construction, since state transition diagrams do not readily document the failure logic process. This
paper introduces a new gate into the fault tree diagram, which enables the reliability analyst to incorporate standby
dependencies. The analysis of the fault tree is then performed by identifying the sections of the fault tree which
conform to the usual requirements of independence and those which do not. Using a combination of conventional
fault tree analysis methods with Markov methods, the analysis of the tree is performed by computer code in a
manner that is transparent to the analyst. A similar approach has been developed for the analysis of systems with
sequential failures represented by a PRIORITY AND gate on the fault tree diagram.With these extended fault tree
capabilities in place, the technique has been embedded within an optimization framework to get the best system
performance for systems where failures are dependent.
2008-10-01 15:30:57
Fault trees
Markov
Dependencies
Standby
Sequential