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Probabilistic risk assessment (PRA) is a systematic and comprehensive methodology to evaluate risks associated with a complex engineered technological entity (such as an airliner or a nuclear power plant). Risk in a PRA is defined as a feasible detrimental outcome of an activity or action. In a PRA, risk is characterized by two quantities: #the magnitude (severity) of the possible adverse consequence(s), and #the likelihood (probability) of occurrence of each consequence. Consequences are expressed numerically (e.g., the number of people potentially hurt or killed) and their likelihoods of occurrence are expressed as probabilities or frequencies (i.e., the number of occurrences or the probability of occurrence per unit time). The total risk is the expected loss: the sum of the products of the consequences multiplied by their probabilities. The spectrum of risks across classes of events are also of concern, and are usually controlled in licensing processes – it would be of concern if rare but high consequence events were found to dominate the overall risk, particularly as these risk assessments are very sensitive to assumptions (how rare is a high consequence event?). Probabilistic Risk Assessment usually answers three basic questions: #What can go wrong with the studied technological entity, or what are the initiators or initiating events (undesirable starting events) that lead to adverse consequence(s)? #What and how severe are the potential detriments, or the adverse consequences that the technological entity may be eventually subjected to as a result of the occurrence of the initiator? #How likely to occur are these undesirable consequences, or what are their probabilities or frequencies? Two common methods of answering this last question are Event Tree Analysis and Fault Tree Analysis - for explanations of these, see safety engineering. In addition to the above methods, PRA studies require special but often very important analysis tools like human reliability analysis (HRA) and common-cause-failure analysis (CCF). HRA deals with methods for modeling human error while CCF deals with methods for evaluating the effect of inter-system and intra-system dependencies which tend to cause simultaneous failures and thus significant increases in overall risk. In 2007 France was criticised for failing to use a PRA approach to evaluate the seismic risks of French nuclear power plants.〔(Centrale Nucléaire de Fessenheim : appréciation du risque sismique ) RÉSONANCE Ingénieurs-Conseils SA, published 2007-09-05, accessed 2011-03-30〕 ==Criticism== Theoretically, the probabilistic risk assessment method suffers from several problems:
In the case of many accidents, probabilistic risk assessment models do not account for unexpected failure modes:〔
When it comes to future safety, nuclear designers and operators often assume that they know what is likely to happen, which is what allows them to assert that they have planned for all possible contingencies. Yet there is one weakness of the probabilistic risk assessment method that has been emphatically demonstrated with the Fukushima I nuclear accidents -- the difficulty of modeling common-cause or common-mode failures:〔
However, a PRA analysis that assumed an initiating event of a beyond design basis tsunami of the magnitude that occurred would have identified most, if not all, of the above consequences. In this case, the challenge is not with the PRA method but with the selection of initiating events. For any given design, a low probability high magnitude initiating event can be assumed for which the design will fail. However, selecting an unrealistically severe initiator defeats the purpose of the analysis, as potential vulnerabilities to realistic scenarios will be masked. 抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)』 ■ウィキペディアで「Probabilistic risk assessment」の詳細全文を読む スポンサード リンク
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