Probabilistic Risk Analysis: Foundations and Methods,9780521773201

Probabilistic Risk Analysis: Foundations and Methods

by
ISBN13: 9780521773201
ISBN10: 0521773202
Format: Hardcover
Pub. Date: 2001-04-30
Publisher(s): Cambridge University Press
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Summary

Probabilistic risk analysis aims to quantify the risk caused by high technology installations. Increasingly, such analyses are being applied to a wider class of systems in which problems such as lack of data, complexity of the systems, uncertainty about consequences, make a classical statistical analysis difficult or impossible. The authors discuss the fundamental notion of uncertainty, its relationship with probability, and the limits to the quantification of uncertainty. Drawing on extensive experience in the theory and applications of risk analysis, the authors focus on the conceptual and mathematical foundations underlying the quantification, interpretation and management of risk. They cover standard topics as well as important new subjects such as the use of expert judgement and uncertainty propagation. The relationship of risk analysis with decision making is highlighted in chapters on influence diagrams and decision theory. Finally, the difficulties of choosing metrics to quantify risk, and current regulatory frameworks are discussed.

Table of Contents

Illustrations
xiii
Tables
xvi
Preface xix
Part I: Introduction 1(14)
Probabilistic risk analysis
3(12)
Historical overview
4(5)
The aerospace sector
4(1)
The nuclear sector
5(3)
The chemical process sector
8(1)
The less recent past
9(1)
What is the definition of risk?
9(2)
Scope of probabilistic risk analyses
11(1)
Risk analysis resources
12(3)
Important journals
12(1)
Handbooks
12(1)
Professional organizations
12(1)
Internet
13(2)
Part II: Theoretical issues and background 15(82)
What is uncertainty?
17(22)
The meaning of meaning
17(2)
The meaning of uncertainty
19(2)
Probability axioms
21(3)
Interpretations
22(2)
Savage's theory of rational decision
24(6)
Savage's axioms
26(2)
Quantitative probability
28(1)
Utility
28(1)
Observation
28(2)
Measurement of subjective probabilities
30(3)
Different types of uncertainty
33(2)
Uncertainty about probabilities
35(4)
Probabilistic methods
39(22)
Review of elementary probability theory
39(2)
Random variables
41(6)
Moments
42(1)
Several random variables
43(1)
Correlations
44(1)
Failure rates
45(2)
The exponential life distribution
47(4)
Constant test intervals
48(2)
Exponential failure and repair
50(1)
The Poisson distribution
51(1)
The gamma distribution
52(1)
The beta distribution
53(1)
The lognormal distribution
54(1)
Stochastic processes
55(3)
Approximating distributions
58(3)
Statistical inference
61(22)
Foundations
61(2)
Bayesian inference
63(12)
Bayes' Theorem
64(3)
An example with the exponential distribution
67(2)
Conjugate distributions
69(1)
First find your prior
70(4)
Point estimators from the parameter distribution
74(1)
Asymptotic behaviour of the posterior
74(1)
Classical statistical inference
75(8)
Estimation of parameters
75(2)
Non-parametric estimation
77(1)
Confidence intervals
78(1)
Hypothesis testing
79(4)
Weibull Analysis
83(14)
Definitions
85(1)
Graphical methods for parameter fitting
85(7)
Rank order methods
86(2)
Suspended or censored items
88(3)
The Kaplan-Meier estimator
91(1)
Maximum likelihood methods for parameter estimation
92(2)
Bayesian estimation
94(1)
Extreme value theory
94(3)
Part III: System analysis and quantification 97(160)
Fault and event trees
99(22)
Fault and event trees
99(1)
The aim of a fault-tree analysis
100(3)
The definition of a system and of a top event
103(1)
External boundaries
103(1)
Internal boundaries
104(1)
Temporal boundaries
104(1)
What classes of faults can occur?
104(2)
Active and passive components
105(1)
Primary, secondary and command faults
105(1)
Failure modes, effects and mechanisms
105(1)
Symbols for fault trees
106(1)
Fault tree construction
106(2)
Examples
108(2)
Reactor vessel
108(1)
New Waterway barrier
109(1)
Minimal path and cut sets for coherent systems
110(2)
Cut sets
110(2)
Path sets
112(1)
Set theoretic description of cut and path sets
112(5)
Boolean algebra
112(2)
Cut set representation
114(1)
Path set representation
115(1)
Minimal cut set/path set duality
115(2)
Parallel and series systems
117(1)
Estimating the probability of the top event
117(4)
Common cause
118(3)
Fault trees - analysis
121(19)
The MOCUS algorithm for finding minimal cut sets
121(2)
Top down substitution
121(1)
Bottom up substitution
122(1)
Tree pruning
122(1)
Binary decision diagrams and new algorithms
123(12)
Prime implicants calculation
129(1)
Minimal p-cuts
130(2)
Probability calculations
132(1)
Examples
132(2)
The size of the BDD
134(1)
Importance
135(5)
Dependent failures
140(13)
Introduction
140(1)
Component failure data versus incident reporting
140(1)
Preliminary analysis
141(2)
Inter-system dependencies
143(1)
Inter-component dependencies - common cause failure
143(1)
The square root bounding model
143(1)
The Marshall-Olkin model
143(3)
The beta-factor model
146(2)
Parameter estimation
147(1)
The binomial failure rate model
148(3)
The α-factor model
151(1)
Other models
151(2)
Reliability data bases
153(38)
Introduction
153(3)
Maintenance and failure taxonomies
156(4)
Maintenance taxonomy
156(1)
Failure taxonomy
157(1)
Operating modes; failure causes; failure mechanisms and failure modes
158(2)
Data structure
160(3)
Operations on data
161(2)
Data analysis without competing risks
163(3)
Demand related failures: non-degradable components
163(1)
Demand related failures: degradable components
164(1)
Time related failures: no competing risks
165(1)
Competing risk concepts and methods
166(6)
Subsurvivor functions and identifiability
168(2)
Colored Poisson representation of competing risks
170(2)
Competing risk models
172(7)
Independent exponential competing risk
172(3)
Random clipping
175(1)
Random signs
175(2)
Conditionally independent competing risks
177(2)
Time window censoring
179(1)
Uncertainty
179(5)
Uncertainty due to non-identifiability: bounds in the absence of sampling fluctuations
180(2)
Accounting for sampling fluctuations
182(1)
Sampling fluctuations of Peterson bounds
182(2)
Examples of dependent competing risk models
184(7)
Failure effect
185(1)
Action taken
186(2)
Method of detection
188(1)
Subcomponent
189(1)
Conclusions
189(2)
Expert opinion
191(27)
Introduction
191(1)
Generic issues in the use of expert opinion
192(1)
Bayesian combinations of expert assessments
192(2)
Non-Bayesian combinations of expert distributions
194(5)
Linear opinion pools
199(1)
Performance based weighting - the classical model
199(9)
Calibration
200(2)
Information
202(1)
Determining the weights
203(3)
Approximation of expert distributions
206(2)
Case study -- uncertainty in dispersion modeling
208(10)
Human reliability
218(22)
Introduction
218(2)
Generic aspects of a human reliability analysis
220(4)
Human error probabilities
220(1)
Task analysis
220(1)
Performance and error taxonomy
221(2)
Performance shaping factors
223(1)
THERP - technique for human error rate prediction
224(6)
Human error event trees
226(1)
Performance shaping factors
227(1)
Dependence
227(1)
Time dependence and recovery
228(1)
Distributions for HEPs
228(2)
The Success Likelihood Index Methodology
230(2)
Time reliability correlations
232(3)
Absolute Probability Judgement
235(1)
Influence diagrams
236(2)
Conclusions
238(2)
Software reliability
240(17)
Qualitative assessment - ways to find errors
240(2)
FMECAs of software-based systems
240(1)
Formal design and analysis methods
241(1)
Software sneak analysis
241(1)
Software testing
241(1)
Error reporting
242(1)
Software quality assurance
242(3)
Software safety life-cycles
242(1)
Development phases and reliability techniques
243(2)
Software quality
245(1)
Software quality characteristics
245(1)
Software quality metrics
245(1)
Software reliability prediction
245(6)
Error seeding
247(1)
The Jelinski--Moranda model
247(1)
Littlewood's model
248(1)
The Littlewood-Verral model
249(1)
The Goel--Okumoto model
250(1)
Calibration and weighting
251(2)
Calibration
251(2)
Weighted mixtures of predictors
253(1)
Integration errors
253(2)
Example
255(2)
Part IV: Uncertainty modeling and risk measurement 257(116)
Decision theory
259(27)
Preferences over actions
261(1)
Decision tree example
262(2)
The value of information
264(4)
When do observations help?
267(1)
Utility
268(1)
Multi-attribute decision theory and value models
269(12)
Attribute hierarchies
270(1)
The weighting factors model
271(1)
Mutual preferential independence
271(3)
Conditional preferential independence
274(3)
Multi-attribute utility theory
277(3)
When do we model the risk attitude?
280(1)
Trade-offs through time
281(1)
Other popular models
281(2)
Cost-benefit analysis
281(2)
The analytic hierarchy process
283(1)
Conclusions
283(3)
Influence diagrams and belief nets
286(13)
Belief networks
286(2)
Conditional independence
288(1)
Directed acyclic graphs
289(1)
Construction of influence diagrams
290(4)
Model verification
292(2)
Operations on influence diagrams
294(1)
Arrow reversal
294(1)
Chance node removal
294(1)
Evaluation of influence diagrams
295(1)
The relation with decision trees
295(1)
An example of a Bayesian net application
296(3)
Project risk management
299(17)
Risk management methods
300(2)
Identification of uncertainties
300(2)
Quantification of uncertainties
302(1)
Calculation of project risk
302(1)
The Critical Path Method (CPM)
302(2)
Expert judgement for quantifying uncertainties
304(1)
Building in correlations
305(1)
Simulation of completion times
305(1)
Value of money
306(1)
Case study
307(9)
Probabilistic inversion techniques for uncertainty analysis
316(10)
Elicitation variables and target variables
318(1)
Mathematical formulation of probabilistic inversion
319(1)
Prejudice
320(2)
Heuristics
320(1)
Solving for minimum information
321(1)
Infeasibility problems and PARFUM
322(1)
Example
323(3)
Uncertainty analysis
326(24)
Introduction
326(1)
Mathematical formulation of uncertainty analysis
326(1)
Monte Carlo simulation
327(12)
Univariate distributions
327(1)
Multivariate distributions
328(1)
Transforms of joint normals
329(1)
Rank correlation trees
330(4)
Vines
334(5)
Examples: uncertainty analysis for system failure
339(7)
The reactor example
339(2)
Series and parallel systems
341(1)
Dispersion model
342(4)
Appendix: bivariate minimally informative distributions
346(4)
Minimal information distributions
346(4)
Risk measurement and regulation
350(23)
Single statistics representing risk
350(5)
Deaths per million
350(1)
Loss of life expectancy
351(2)
Delta yearly probability of death
353(1)
Activity specific hourly mortality rate
354(1)
Death per unit activity
355(1)
Frequency vs consequence lines
355(7)
Group risk comparisons; ccdf method
356(3)
Total risk
359(1)
Expected disutility
360(1)
Uncertainty about the fC curve
361(1)
Benefits
362(1)
Risk regulation
362(3)
ALARP
362(1)
The value of human life
363(2)
Limits of risk regulation
365(1)
Perceiving and accepting risks
365(4)
Risk perception
367(1)
Acceptability of risks
368(1)
Beyond risk regulation: compensation, trading and ethics
369(4)
Bibliography 373(17)
Index 390

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