1. STAT 572: Bootstrap Project Group Members: Cindy Bothwell Erik Barry Erhardt Nina Greenberg Casey Richardson Zachary Taylor

2. Histograms of Complex Population Distribution

3. Histograms of Population Sampling Distribution of the Median and Estimated Bootstrap Sampling Distributions

4. What is a Bootstrap A method of Resampling: creating many samples from a single sample Generally, resampling is done with replacement Used to develop a sampling distribution of statistics such as mean, median, proportion, others.

5. The Bootstrap and Complex Surveys Number of bootstrap samples – n = sample size, N = population size – Possible resamples n n (example n=200, 200 200 =1.6x10 460 ) Too many possibilities N!/[n!(N-n)!], limit to B a large number, (example = 1000) - the Monte Carlo approximation Determine sampling distribution with parameters Calculate variance in the normal way

6. Advantages and Disadvantages Advantages: – Avoids the costs of taking new samples (Estimate a sampling distribution when only one sample is available) – Checking parametric assumptions – Used when parametric assumptions cannot be made or are very complicated – Estimation of variance in quantiles Disadvantages: – Relies on a representative sample – Variability due to finite replications (Monte Carlo)

7. Computations With more computing power available, bootstrap is possible for a large number of resamples Possible programs: – Matlab – Minitab – SAS – Excel – S-Plus – SPSS – Fathom

8. Bootstrap using SURVEY program Main parameter of interest is the median price that all households in Lockhart City are wiling to pay for cable. The price that a household is willing to pay for cable is positively correlated with average-district house value. Districts in Lockhart City are divided into strata based on average house value. Estimate the variance and create 95% CI

9. Lockhart City Strata Characteristics: Take a stratified random sample of size 200 using proportional allocation. Using the stratified random sample, implement the general bootstrap procedure, BWO, and mirror- match.

10. Variations of the Bootstrap in Strata General Bootstrap – Mimic the original sampling method BWO: Bootstrap Without Replacement – Grow the sample to the size of the population Mirror-Match – Repeated miniature resamples

11. BWO: Bootstrap Without Replacement Grow the sample to the size of the population For each stratum L, create a pseudo- population by replicating the sample k L times. Resample n’ L units from each stratum without replacement to obtain a single bootstrap sample for stratum L. Repeat a large number of times

12. BWO: Variable Definitions

13. Disadvantages of extended BWO N L must be known n’ L and k L are often non-integers Must bracket between integers if n’ L and k L are non-integer Computing time

14. Mirror-Match Repeated miniature resamples Resample size is determined to match the proportion of the original sample size to the population sample size (n L /N L ). Using the resample size n’ L, we resample n’ L units (SRSWOR) from each stratum L. Repeat previous step k L times with replacement to obtain a single bootstrap sample for stratum L. Repeat a large number times

15. Mirror-Match: Variable Definitions

16. Mirror Match: Disadvantages N L must be known k L is often non-integer Must bracket between integers when k L is non-integer Computing time

17. Estimation of the Population Sampling Distributions 100,000 independent stratified random samples. Medians computed and plotted to form empirical sampling distributions. Variables: house value, cable price, and TV hours.

18. Estimation of the Population Sampling Distributions

19. Simulations Matlab code: General, BWO, and Mirror-match. Two independent stratified random samples from Lockhart City. Comparison of the sample bootstrap sampling distributions with the population sampling distributions. 95% confidence intervals were determined bootstrap 2.5 and 97.5 percentiles.

20. Sampling Distributions 1

21. Sampling Distributions 2

22. Confidence Intervals

23. The Empirical verses the Bootstrap Sampling Distributions Bootstrap sampling distributions are expected to mimic actual sampling distributions. Bootstrap sampling is sensitive to individual samples. The shape of bootstrap sampling distributions may vary, but the statistic of interest and its variance are considered accurate.

24. Comparison of Bootstrap Methods

25. Empirical Coverages The empirical coverages were close to the expected 95%. They differed very little between the different bootstrap procedures.

26. Empirical Coverages Empirical coverages are dependent on the type of confidence interval that was originally selected. Our confidence intervals were calculated from the 2.5 and 97.5 percentiles of each bootstrap distribution. There are many different types of bootstrap confidence intervals. The one we selected, although intuitive in design, is considered generally biased (Bedrick 2006).

27. Computer Processing Times Computer processing times varied greatly. Mean processing time per sample in seconds.

28. Computer Processing Times BWO took 381 times as long as general bootstrapping procedures. Mirror-match took 293 times as long as general bootstrapping procedures. For our study, the BWO and mirror-match conferred no advantage over general bootstrapping with regard to statistical estimates. However, their vastly greater processing times are a great disadvantage.

29. CONCLUSIONS: General Bootstrap verses BWO and Mirror-Match BWO and Mirror-match procedures are designed to mimic complex sampling designs. We only analyzed stratified samples of 200 from a fictitious city. BWO and Mirror-match methods may be advantageous in other complex sampling scenarios.