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| Szimulációval támogatott Hiba-üzemmód és hatáselemzés× | Szimulációval támogatott megbízhatóságanalízis× | |
|---|---|---|
| Tudományterület | Kísérlettervezés | Kísérlettervezés |
| Módszercsalád | Process / pipeline | Process / pipeline |
| Keletkezés éve≠ | 1949 (FMEA); simulation-assisted variant: 1980s–1990s | 1940s–1980s (Monte Carlo foundations ~1940s; simulation-reliability integration ~1970s–1980s) |
| Megalkotó≠ | FMEA originates from US MIL-P-1629 (1949); simulation integration developed in reliability engineering from the 1980s–1990s | Enrico Fermi, John von Neumann, Stanislaw Ulam (Monte Carlo foundations); Freudenthal (structural reliability); Melchers (simulation integration) |
| Típus≠ | Reliability and risk analysis method | Quantitative probabilistic engineering method |
| Alapmű≠ | Stamatis, D. H. (2003). Failure Mode and Effect Analysis: FMEA from Theory to Execution (2nd ed.). ASQ Quality Press. ISBN: 978-0873895989 | Melchers, R. E., & Beck, A. T. (2018). Structural Reliability Analysis and Prediction (3rd ed.). Wiley. ISBN: 978-1119266075 |
| Alternatív nevek | Simulation-FMEA, Monte Carlo FMEA, Simulation-based FMEA, SA-FMEA | SARA, Monte Carlo reliability analysis, simulation-based reliability assessment, virtual reliability testing |
| Kapcsolódó | 6 | 6 |
| Összefoglaló≠ | Simulation-assisted FMEA enhances the classical Failure Mode and Effects Analysis by replacing point-estimate occurrence ratings with probabilistic simulation — typically Monte Carlo — to quantify failure probability distributions across a system's components. This yields statistically grounded Risk Priority Numbers (RPNs) rather than expert guesses, enabling more rigorous identification and prioritization of critical failure modes in complex engineering systems. | Simulation-assisted reliability analysis combines probabilistic reliability theory with computational simulation — most commonly Monte Carlo methods or finite-element models — to estimate the probability that a system, component, or structure will perform its intended function under uncertain operating conditions. Rather than relying solely on closed-form analytical solutions, it propagates uncertainty through high-fidelity numerical models to quantify failure risk across complex, nonlinear, or multi-failure-mode systems. |
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