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Three or More Factors: Latin Squares

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1 Three or More Factors: Latin Squares
Example: Three factors, A (block factor), B (block factor), and C (treatment factor), each at three levels. A possible arrangement: B B B 1 2 3 C C C A 1 1 1 1 A C C C 2 2 2 2 A C C C 3 3 3 3

2 Notice, first, that these designs are squares; all factors are at the same number of levels, though there is no restriction on the nature of the levels themselves. Notice, that these squares are balanced: each letter (level) appears the same number of times; this insures unbiased estimates of main effects. How to do it in a square? Each treatment appears once in every column and row. Notice, that these designs are incomplete; of the 27 possible combinations of three factors each at three levels, we use only 9.

3 Example: Three factors, A (block factor), B (block factor), and C (treatment factor), each at three levels, in a Latin Square design; nine combinations. B B B 1 2 3 C C C A 1 2 3 1 A C C C 2 2 3 1 A C C C 3 3 1 2

4 Example with 4 Levels per Factor
FACTORS VARIABLE Automobiles A four levels Tire positions B four levels Tire treatments C four levels Lifetime of a tire (days) A 1 2 3 4 B C 8 5 7 9 6

5 The Model for (Unreplicated) Latin Squares
Example: Three factors r , t and g each at m levels i = 1,... m y = + + + + j = 1, ... , m ijk j k ijk i Y = A + B + C + e k ... , = 1, m AB, AC, BC, ABC Note that interaction is not present in the model. Same three assumptions: normality, constant variances, and randomness.

6 Putting in Estimates: y = y + ( y – y ) + ( y – y ) + ( y – y ) + R y
ijk ... i .. ... . j . ... .. k ... or bringing y••• to the left hand side , ( y y ) = ( y y ) + ( y y ) + ( y y ) + R , ijk ... i .. ... . j . ... .. k ... Variability among yields associated with Rows Variability among yields associated with Columns Variability among yields associated with Inside Factor Total variability among yields = + + y y y y + 2 y where R = ijk i .. . j . .. k ...

7 An “interaction-like” term. (After all, there’s no replication!)
Actually, R = y - y - y - y + 2 y ijk i .. . j . .. k ... = ( y - y ) ( y - y ) - ijk ... i .. ... y y ) - ( - . j . ... - ( y - y ), .. k ... An “interaction-like” term. (After all, there’s no replication!)

8 The analysis of variance (omitting the mean squares, which are the ratios of second to third entries), and expectations of mean squares: S o u r c e o f S u m o f D e g r e e s o f E x p e c t e d v a r i a t i o n s q u a r e s f r e e d o m v a l u e o f m e a n s q u a r e R o w s m m 1 2 + V m ( y y ) 2 Rows i .. ... i = 1 C o l u m n s m m 1 2 + V m ( y y ) 2 Col . j . ... j = 1 I n s i d e m m 1 2 + V m ( y y ) 2 Inside factor f a c t o r .. k ... k = 1 b y s u b t r a c t i o n ( m 1)( m 2) 2 Error T o t a l ( y y ) 2 m 2 1 ijk ... i j k

9 The expected values of the mean squares immediately suggest the F ratios appropriate for testing null hypotheses on rows, columns and inside factor.

10 (Inside factor = Tire Treatment)
Our Example: (Inside factor = Tire Treatment) Tire Position Auto.

11 General Linear Model: Lifetime versus Auto, Postn, Trtmnt Factor Type Levels Values Auto fixed Postn fixed Trtmnt fixed Analysis of Variance for Lifetime, using Adjusted SS for Tests Source DF Seq SS Adj SS Adj MS F P Auto Postn Trtmnt Error Total Unusual Observations for Lifetime Obs Lifetime Fit SE Fit Residual St Resid R

12

13 SPSS/Minitab DATA ENTRY VAR1. VAR2. VAR3. VAR4 855. 1. 1. 4 962. 2. 1

14 Latin Square with REPLICATION
Case One: using the same rows and columns for all Latin squares. Case Two: using different rows and columns for different Latin squares. Case Three: using the same rows but different columns for different Latin squares.

15 Treatment Assignments for n Replications
Case One: repeat the same Latin square n times. Case Two: randomly select one Latin square for each replication. Case Three: randomly select one Latin square for each replication.

16 Example: n = 2, m = 4, trtmnt = A,B,C,D
Case One: column row 1 2 3 4 A B C D column row 1 2 3 4 A B C D Row = 4 tire positions; column = 4 cars

17 Row = clinics; column = patients; letter = drugs for flu
Case Two column row 1 2 3 4 A B C D column row 5 6 7 8 B C D A Row = clinics; column = patients; letter = drugs for flu

18 Row = 4 tire positions; column = 8 cars
Case Three column row 1 2 3 4 A B C D 5 6 7 8 B C D A Row = 4 tire positions; column = 8 cars

19 ANOVA for Case 1 SSBR, SSBC, SSBIF are computed the same way as before, except that the multiplier of (say for rows) m (Yi..-Y…)2 becomes mn (Yi..-Y…)2 and degrees of freedom for error becomes (nm2 - 1) - 3(m - 1) = nm2 - 3m + 2

20 ANOVA for other cases: SS: please refer to the book, Statistical Principles of research Design and Analysis by R. Kuehl. DF: # of levels – 1 for all terms except error. DF of error = total DF – the sum of the rest DF’s. Using Minitab in the same way can give Anova tables for all cases.

21 Graeco-Latin Squares m – 1 = m + 1 m – 1
In an unreplicated m x m Latin square there are m2 yields and m2 - 1 degrees of freedom for the total sum of squares around the grand mean. As each studied factor has m levels and, therefore, m-1 degrees of freedom, the maximum number of factors which can be accommodated, allowing no degree of freedom for factors not studied, is A design accommodating the maximum number of factors is called a complete Graeco-Latin square: m 1 2 = m + 1 m 1

22 Example 1: m=3; four factors can be accommodated

23 Example 2: m = 5; six factors can be accommodated

24 In an unreplicated complete Graeco-Latin square all degrees of freedom are used up by factors studied. Thus, no estimate of the effect of factors not studied is possible, and analysis of variance cannot be completed.

25 But, consider incomplete Graeco-Latin Squares:
b b b b b5 a1 c1d1 c2d2 c3d3 c4d4 c5d5 a2 c2d3 c3d4 c4d5 c5d1 c1d2 a3 c3d5 c4d1 c5d2 c1d3 c2d4 a4 c4d2 c5d3 c1d4 c2d5 c3d1 a5 c5d4 c1d5 c2d1 c3d2 c4d3

26 We test 4 different Hypotheses.
ANOVA TABLE SOURCE SSQ df A B C D Error SSBA SSBB SSBC SSBD SSW 4 8 by Subtraction TSS

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