1. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 1

2. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 2 Design of Engineering Experiments - Experiments with Random Factors Text reference, Chapter 13 Previous chapters have focused primarily on fixed factors –A specific set of factor levels is chosen for the experiment –Inference confined to those levels –Often quantitative factors are fixed (why?) When factor levels are chosen at random from a larger population of potential levels, the factor is random –Inference is about the entire population of levels –Industrial applications include measurement system studies –It has been said that failure to identify a random factor as random and not treat it properly in the analysis is one of the biggest errors committed in DOX The random effect model was introduced in Chapter 3

3. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 3 Extension to Factorial Treatment Structure Two factors, factorial experiment, both factors random (Section 13.2, pg. 574) The model parameters are NID random variables Random effects model

4. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 4 Testing Hypotheses - Random Effects Model Once again, the standard ANOVA partition is appropriate Relevant hypotheses: Form of the test statistics depend on the expected mean squares:

5. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 5 Estimating the Variance Components – Two Factor Random model As before, we can use the ANOVA method; equate expected mean squares to their observed values: These are moment estimators Potential problems with these estimators

6. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 6 Example 13.1 A Measurement Systems Capability Study Gauge capability (or R&R) is of interest The gauge is used by an operator to measure a critical dimension on a part Repeatability is a measure of the variability due only to the gauge Reproducibility is a measure of the variability due to the operator See experimental layout, Table 13.1. This is a two-factor factorial (completely randomized) with both factors (operators, parts) random – a random effects model

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8. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 8 Example 13.1 Minitab Solution – Using Balanced ANOVA

9. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 9 Example 13.2 Minitab Solution – Balanced ANOVA There is a large effect of parts (not unexpected) Small operator effect No Part – Operator interaction Negative estimate of the Part – Operator interaction variance component Fit a reduced model with the Part – Operator interaction deleted

10. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 10 Example 13.1 Minitab Solution – Reduced Model

11. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 11 Example 13.1 Minitab Solution – Reduced Model Estimating gauge capability: If interaction had been significant?

12. Maximum Likelihood Approach Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 12

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16. CI on the Variance Components Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 16 The lower and upper bounds on the CI are:

17. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 17 The Two-Factor Mixed Model Two factors, factorial experiment, factor A fixed, factor B random (Section 13.3, pg. 581) The model parameters are NID random variables, the interaction effects are normal, but not independent This is called the restricted model

18. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 18 Testing Hypotheses - Mixed Model Once again, the standard ANOVA partition is appropriate Relevant hypotheses: Test statistics depend on the expected mean squares:

19. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 19 Estimating the Variance Components – Two Factor Mixed model Use the ANOVA method; equate expected mean squares to their observed values: Estimate the fixed effects (treatment means) as usual

20. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 20 Example 13.2 The Measurement Systems Capability Study Revisited Same experimental setting as in example 13.1 Parts are a random factor, but Operators are fixed Assume the restricted form of the mixed model Minitab can analyze the mixed model and estimate the variance components

21. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 21 Example 13.2 Minitab Solution – Balanced ANOVA

22. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 22 Example 13.2 Minitab Solution – Balanced ANOVA There is a large effect of parts (not unexpected) Small operator effect No Part – Operator interaction Negative estimate of the Part – Operator interaction variance component Fit a reduced model with the Part – Operator interaction deleted This leads to the same solution that we found previously for the two-factor random model

23. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 23 The Unrestricted Mixed Model Two factors, factorial experiment, factor A fixed, factor B random (pg. 583) The random model parameters are now all assumed to be NID

24. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 24 Testing Hypotheses – Unrestricted Mixed Model The standard ANOVA partition is appropriate Relevant hypotheses: Expected mean squares determine the test statistics:

25. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 25 Estimating the Variance Components – Unrestricted Mixed Model Use the ANOVA method; equate expected mean squares to their observed values: The only change compared to the restricted mixed model is in the estimate of the random effect variance component

26. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 26 Example 13.3 Minitab Solution – Unrestricted Model

27. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 27 Finding Expected Mean Squares Obviously important in determining the form of the test statistic In fixed models, it’s easy: Can always use the “brute force” approach – just apply the expectation operator Straightforward but tedious Rules on page 523-524 work for any balanced model Rules are consistent with the restricted mixed model – can be modified to incorporate the unrestricted model assumptions

28. JMP Output for the Mixed Model – using REML Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 28

29. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 29 Approximate F Tests Sometimes we find that there are no exact tests for certain effects (page 525) Leads to an approximate F test (“pseudo” F test) Test procedure is due to Satterthwaite (1946), and uses linear combinations of the original mean squares to form the F-ratio The linear combinations of the original mean squares are sometimes called “synthetic” mean squares Adjustments are required to the degrees of freedom Refer to Example 13.7 Minitab will analyze these experiments, although their “synthetic” mean squares are not always the best choice

30. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 30 Notice that there are no exact tests for main effects

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36. Chapter 13Design & Analysis of Experiments 8E 2012 Montgomery 36 We chose a different linear combination

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