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Summarizing Risk Analysis Results To quantify the risk of an output variable, 3 properties must be estimated: A measure of central tendency (e.g. µ ) A.

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Presentation on theme: "Summarizing Risk Analysis Results To quantify the risk of an output variable, 3 properties must be estimated: A measure of central tendency (e.g. µ ) A."— Presentation transcript:

1 Summarizing Risk Analysis Results To quantify the risk of an output variable, 3 properties must be estimated: A measure of central tendency (e.g. µ ) A measure of dispersion (e.g. σ or range) The shape of the distribution describes which values are more likely than others to occur Histograms and proportions

2 Sources of Uncertainty Inherent risk of output variable Measured by range and  Determined by risk specified for input variables Sampling risk Associated with size of sample (e.g. number of iterations) and likelihood of error in parameter estimate

3 Estimation Sample Statistics are used to estimate Population Parameters is used to estimate Population Mean,  Problem: Different samples provide different estimates of the population parameter A sampling distribution describes the likelihood of different sample estimates that can be obtained from a population _

4 Developing Sampling Distributions Assume there is a population … Population size N=4 Random variable, X, is age of individuals Values of X: 18, 20, 22, 24 measured in years A B C D

5 .3.2.1 0 A B C D (18) (20) (22) (24) Uniform Distribution P(X) X Developing Sampling Distributions (continued) Summary Measures for the Population Distribution

6 All Possible Samples of Size n=2 16 Samples Taken with Replacement 16 Sample Means Developing Sampling Distributions (continued)

7 Sampling Distribution of All Sample Means 18 19 20 21 22 23 24 0.1.2.3 P(X) X Sample Means Distribution 16 Sample Means _ Developing Sampling Distributions (continued)

8 Properties of Summary Measures i.e. is unbiased Standard error (standard deviation) of the sampling distribution when sampling with replacement: As n increases, decreases Sampling more decreases the uncertainty in the estimate for 

9 Comparing the Population with its Sampling Distribution 18 19 20 21 22 23 24 0.1.2.3 P(X) X Sample Means Distribution n = 2 A B C D (18) (20) (22) (24) 0.1.2.3 Population N = 4 P(X) X _

10 Central Limit Theorem As sample size gets large enough… the sampling distribution becomes almost normal regardless of shape of population

11 Confidence Interval for µ One can be 95% confident that the true mean of an output variable falls somewhere between the following limits:

12 Descriptions of Shape Histograms; Percentiles Measures of symmetry Skewness Weighted average cube of distance from mean divided by the cube of the standard deviation Symmetric distributions have 0 skew Positively skewed: tail to right side is longer than that to the left Outcomes are biased towards larger values Mean > median > mode

13 Population Proportions Proportion of population having a characteristic Sample proportion provides an estimate

14 Sampling Distribution of Sample Proportion Mean: Standard error: p = population proportion Sampling Distribution P(p s ).3.2.1 0 0. 2.4.6 8 1 psps

15 Confidence Interval for p One can be 95% confident that the true proportion for an output variable that has a certain characteristic falls somewhere between the following limits:

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