Experimental Statistics - week 5

1. Experimental Statistics - week 5 Chapters 8, 9:Miscellaneous topicsChapter 14:Experimental design conceptsChapter 15:Randomized Complete Block Design (15.3)

2. 1-Factor ANOVA Model yij = mi+ eij or yij = m + ai+ eij observed data unexplained part mean for ith treatment

3. were rewritten as:

4. In words: TSS(total SS) = total sample variability among yijvalues SSB(SS “between”) = variability explained by differences in group means SSW(SS “within”) = unexplained variability (within groups)

5. Analysis of Variance Table Note:unequal sample sizes allowed

6. Extracted from From Ex. 8.2, page 390-391 3 Methods for Reducing Hostility 12 students displaying similar hostility were randomly assigned to 3 treatment methods. Scores (HLT) at end of study recorded. Method 1 96 79 91 85 Method 2 77 76 74 73 Method 3 66 73 69 66 Test:

7. ANOVA Table Output – extracted hostility data - calculations done in class Source SS df MS Fp-value Between 767.17 2 383.58 16.7 <.001   samples Within 205.74 9 22.86   samples Totals 972.91

8. Fisher’s Least Significant Difference (LSD) Protected LSD:Preceded by an F-test for overall significance. Only use the LSD if F is significant. X Unprotected:Not preceded by an F-test (like individual t-tests).

9. Hostility Data - Completely Randomized Design The GLM Procedure t Tests (LSD) for score NOTE: This test controls the Type I comparisonwise error rate, not the experimentwise error rate. Alpha 0.05 Error Degrees of Freedom 9 Error Mean Square 22.86111 Critical Value of t 2.26216 Least Significant Difference 7.6482 Means with the same letter are not significantly different. t Grouping Mean N method A 87.750 4 1 B 75.000 4 2 B B 68.500 4 3

10. Ex. 8.2, page 390-391 3 Methods for Reducing Hostility 24 students displaying similar hostility were randomly assigned to 3 treatment methods. Scores (HLT) at end of study recorded. Method 1 96 79 91 85 83 91 82 87 Method 2 77 76 74 73 78 71 80 Method 3 66 73 69 66 77 73 71 70 74 Notice unequal sample sizes Test:

11. ANOVA Table Output – full hostility data Source SS df MS F p-value Between 1090.6 2 545.3 29.57 <.0001   samples Within 387.2 21 18.4   samples Totals 1477.8 23

12. The GLM Procedure t Tests (LSD) for score NOTE: This test controls the Type I comparisonwise error rate, not the experimentwise error rate. Alpha 0.05 Error Degrees of Freedom 21 Error Mean Square 18.43878 Critical Value of t 2.07961 Comparisons significant at the 0.05 level are indicated by ***. Difference method Between 95% Confidence Comparison Means Limits 1 - 2 11.179 6.557 15.800 *** 1 - 3 15.750 11.411 20.089 *** 2 - 1 -11.179 -15.800 -6.557 *** 2 - 3 4.571 0.071 9.072 *** 3 - 1 -15.750 -20.089 -11.411 *** 3 - 2 -4.571 -9.072 -0.071 *** Notice the different format since there is not one LSD value with which to make all pairwise comparisons.

13. Duncan's Multiple Range Test for score NOTE: This test controls the Type I comparisonwise error rate, not the experimentwise error rate. Alpha 0.05 Error Degrees of Freedom 21 Error Mean Square 18.43878 Harmonic Mean of Cell Sizes 7.91623 NOTE: Cell sizes are not equal. Number of Means 2 3 Critical Range 4.489 4.712 Means with the same letter are not significantly different. Duncan Grouping Mean N method A 86.750 8 1 B 75.571 7 2 C 71.000 9 3 Note:Duncan’s test (another multiple comparison test) avoids the issue of different sample sizes by using the harmonic mean of the ni’s.

14. Some Multiple Comparison Techniquesin SAS FISHER’S LSD (LSD) BONFERONNI (BON) DUNCAN STUDENT-NEWMAN-KEULS (SNK) DUNNETT RYAN-EINOT-GABRIEL-WELCH (REGWQ) SCHEFFE TUKEY

15. Balloon Data Col. 1-2 - observation number Col. 3 - color (1=pink, 2=yellow, 3=orange, 4=blue) Col. 4-7 - inflation time in seconds 1122.4 2324.6 3120.3 4419.8 5324.3 6222.2 7228.5 8225.7 9320.2 10119.6 11228.8 12424.0 13417.1 14419.3 15324.2 16115.8 17218.3 18117.5 19418.7 20322.9 21116.3 22414.0 23416.6 24218.1 25218.9 26416.0 27220.1 28322.5 29316.0 30119.3 31115.9 32320.3

16. Balloon Data Col. 1-2 - observation number Col. 3 - color (1=pink, 2=yellow, 3=orange, 4=blue) Col. 4-7 - inflation time in seconds 1122.4 2324.6 3120.3 4419.8 5324.3 6222.2 7228.5 8225.7 9320.2 10119.6 11228.8 12424.0 13417.1 14419.3 15324.2 16115.8 17218.3 18117.5 19418.7 20322.9 21116.3 22414.0 23416.6 24218.1 25218.9 26416.0 27220.1 28322.5 29316.0 30119.3 31115.9 32320.3

17. ANOVA --- Balloon Data General Linear Models Procedure Dependent Variable: TIME Sum of Mean Source DF Squares Square F Value Pr > F Model 3 126.15125000 42.05041667 3.85 0.0200 Error 28 305.64750000 10.91598214 Corrected Total 31 431.79875000 R-Square C.V. Root MSE TIME Mean 0.292153 16.31069 3.3039343 20.256250 Mean Source DF Type I SS Square F Value Pr > F Color 3 126.15125000 42.05041667 3.85 0.0200

18. ANOVA --- Balloon Data The GLM Procedure t Tests (LSD) for time NOTE: This test controls the Type I comparisonwise error rate, not the experimentwise error rate. Alpha 0.05 Error Degrees of Freedom 28 Error Mean Square 10.91598 Critical Value of t 2.04841 Least Significant Difference 3.3839 Means with the same letter are not significantly different. t Grouping Mean N color A 22.575 8 2 A A 21.875 8 3 B 18.388 8 1 B B 18.188 8 4

19. Experimental Design: Concepts and Terminology Designed Experiment - an investigation in which a specified framework is used to compare groups or treatments Factors - any feature of the experiment that can be varied from trial to trial - up to this point we’ve only looked at experiments with a single factor

20. Treatments - conditions constructed from the factors (levels of the factor considered, etc.) Experimental Units - subjects, material, etc. to which treatment factors are randomly assigned - there is inherent variability among these units irrespective of the treatment imposed Replication - we usually assign each treatment toseveral experimental units - these are called replicates

21. 1. factor 2. treatments 3. experimental units 4. replicates Examples: Car Data Hostility Data Balloon Data

22. 1122.4 2324.6 3120.3 4419.8 5324.3 6222.2 7228.5 8225.7 9320.2 10119.6 11228.8 12424.0 13417.1 14419.3 15324.2 16115.8 17218.3 18117.5 19418.7 20322.9 21116.3 22414.0 23416.6 24218.1 25218.9 26416.0 27220.1 28322.5 29316.0 30119.3 31115.9 32320.3 Balloon Data Col. 1-2 - observation number (run order) Col. 3 - color (1=pink, 2=yellow, 3=orange, 4=blue) Col. 4-7 - inflation time in seconds Question: Why randomize run order? i.e. why not blow up all the pink balloons first, blue balloons next, etc?

23. Scatterplot Using GPLOT Time Run Order What do we learn from this plot?

24. RECALL: 1-Factor ANOVA Model - random errors follow a Normal (N) distribution, are independently distributed (ID), and have zero mean and constant variance -- i.e. variability does not change from group to group

25. Model Assumptions: - equal variances - normality Checking Validity of Assumptions Equal Variances 1. F-test similar to 2-sample case - Hartley’s test (p.366 text) - not recommended 2. Graphical - side-by-side box plots

26. Graphical Assessment of Equal Variance Assumption

27. Note: Optional approaches if equal variance assumption is violated: 1. Use Kruskal Wallis nonparametric procedure – Section 8.6 2. Transform the data to induce more nearly equal variances – Section 8.5 -- log -- square root Note: These transformations may also help induce normality

28. Assessing Normality of Errors yij = m + ai+ eij so eij = yij -(m + ai) = yij - mi eijis estimated by The eij’s are called residuals.

29. SAS Code for Balloon Data proc glm; class color; model time=color; title 'ANOVA --- Balloon Data'; output out=new r=resball; means color/lsd; run; proc sort; by color; run; proc boxplot; plot time*color; title 'Side-by-Side Box Plots for Balloon Data'; run; proc univariate; var resball; histogram resball/normal; title 'Histogram of Residuals -- Balloon Data'; run; proc univariate normal plot; var resball; title 'Normal Probability Plot for Residuals - Balloon Data'; run; proc gplot; plot time*id; title 'Scatterplot of Time vs ID (Run Order)'; run;

30. Normal Probability Plot 6.5+ +*+ | * *+++ | *+++ | +*+ | *** | **** 0.5+ ***+ | ++** | ++*** | ***** | +*+ | *+*+* -5.5+ * ++++ +----+----+----+----+----+----+----+----+----+----+ -2 -1 0 +1 +2

31. Caution: Chapter 15 introduces some new notation - i.e. changes notation already defined

32. Recall: Sum-of-Squares Identity 1-Factor ANOVA In words: Total SS = SS between samples + within sample SS

33. Recall: Sum-of-Squares Identity 1-Factor ANOVA - new notation for Chapter 15

34. Recall: Sum-of-Squares Identity 1-Factor ANOVA - new notation for Chapter 15

35. Recall: Sum-of-Squares Identity 1-Factor ANOVA - new notation for Chapter 15 In words: Total SS = SS for “treatments” + SS for “error”

36. Revised ANOVA Table for 1-Factor ANOVA(Ch. 15 terminology - p.857) Source SS df MS F Treatments SST t -1 Error SSE N -t Total TSS N -1

37. Recall 1-factor ANOVA (CRD) Model for Gasoline Octane Data yij = mi+ eij or yij = m + ai+ eij observed octane mean for ith gasoline unexplained part -- car-to-car differences -- temperature -- etc.

38. Gasoline Octane Data Question: What if car differences are obscuring gasoline differences? Similar to diet t-test example: Recall: person-to-person differences obscured effect of diet

39. Possible Alternative Design for Octane Study: Test all 5 gasolines on the same car - in essence we test the gasoline effect directly and remove effect of car-to-car variation Question: How would you randomize an experiment with 4 cars?

40. Blocking an Experiment - dividing the observations into groups (called blocks) where the observations in each block are collected under relatively similar conditions - comparisons can many times be made more precisely this way

41. Terminology is based on Agricultural Experiments Consider the problem of testingfertilizers on a crop - t fertilizers - n observations on each

42. Completely Randomized Design B A C A B B A C A C C B C A t = 3 fertilizers n = 5 replications B - randomly select 15 plots - randomly assign fertilizers to the 15 plots

43. Randomized Complete Block Strategy A | C | B B | A | C C | B | A A | B | C t = 3 fertilizers C | A | B - select 5 “blocks” - randomly assign the 3 treatments to each block Note:The 3 “plots” within each block are similar - similar soil type, sun, water, etc

44. Randomized Complete Block Design Randomly assign each treatment once to every block Car Example Car 1: randomly assign each gas to this car Car 2: .... etc. Agricultural Example Randomly assign each fertilizer to one of the 3 plots within each block

45. Model For Randomized Complete Block (RCB) Design yij = m + ai+ bj+ eij effect of ith treatment effect of jth block unexplained error (gasoline) (car) -- temperature -- etc.

46. Previous Data Table from Chapter 8 for 1-factor ANOVA column averages don’t make any sense

47. Back to Octane data: Suppose that instead of 20 cars, there were only 4 cars, and we tested each gasoline on each car. “Restructured” Data Car Old Data Format 1 2 3 4 A 91.7 91.2 90.9 90.6 B 91.7 91.9 90.9 90.9 C 92.4 91.2 91.6 91.0 D 91.8 92.2 92.0 91.4 E 93.1 92.9 92.4 92.4 A 91.7 91.2 90.9 90.6 B 91.7 91.9 90.9 90.9 C 92.4 91.2 91.6 91.0 D 91.8 92.2 92.0 91.4 E 93.1 92.9 92.4 92.4 Gas Gas

48. Recall: Sum-of-Squares Identity 1-Factor ANOVA - using new notation for Chapter 15 In words: Total SS = SS for “treatments” + SS for “error”

49. A New Sum-of-Squares Identity In words: Total SS = SS for treatments + SS for blocks + SS for error

50. Hypotheses: To test for treatmenteffects - i.e. gas differences we test To test for block effects - i.e. car differences (not usually the research hypothesis) we test