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A Williams design is a special Latin square with the additional property of first order carry over (each product is followed equally often by each other product). In R the package crossdes can be used to create them. Want to share your content on R-bloggers? click here if you have a blog, or here if you don't.
> williams(4)
[,1] [,2] [,3] [,4]
[1,] 1 2 4 3
[2,] 2 3 1 4
[3,] 3 4 2 1
[4,] 4 1 3 2
As a consequence of the carry over restriction, the design has the property that a row in this design is also reversed present in the design. Example, row 3 is row 1 reversed. For small designs this property can be used to generate the designs by brute force. Example; a four by four design has without loss of generality the first row and column designated 1 to 4 (using . as unknown).
1 2 3 4
2 . . .
3 . . .
4 . . .
Adding the reversal of the first row gives:
1 2 3 4
2 . . .
3 . . .
4 3 2 1
In practice, for an even number of products the last column can be created as reversed first column.
1 2 3 4
2 . . 3
3 . . 2
4 3 2 1
It is rather obvious that only one solution remains for the 2,2 location and the rest is simple filling in the blanks. The resulting design is the same as the solution of williams(4) with ‘3’ and ‘4’ permuted.
1 2 3 4
2 4 . 3
3 . . 2
4 3 2 1
It is possible to use the same approach for small designs with an even number of products. For an odd number of products the number of rows has to be doubled so this will follow in a later post. To create the design with 6 products a program it is more convenient than manual work. It appears, unknown to many, that using this approach there are two solutions for 6 products. These two solutions are not permutations of each other!
[[1]]
[,1] [,2] [,3] [,4] [,5] [,6]
[1,] 1 2 3 4 5 6
[2,] 2 4 1 6 3 5
[3,] 3 1 5 2 6 4
[4,] 4 6 2 5 1 3
[5,] 5 3 6 1 4 2
[6,] 6 5 4 3 2 1
[[2]]
[,1] [,2] [,3] [,4] [,5] [,6]
[1,] 1 2 3 4 5 6
[2,] 2 4 6 1 3 5
[3,] 3 6 2 5 1 4
[4,] 4 1 5 2 6 3
[5,] 5 3 1 6 4 2
[6,] 6 5 4 3 2 1
There are 8 solutions for 8 products and 192 solutions for 10 products. Above that, calculation time is prohibitive. Even to get to 10, the program had to be streamlined considerably.
R code
gendesign <- function(n=6) {
nr <- as.integer(n)
nc <- nr
desmat <- matrix(NA,nrow=nr,ncol=nc)
desmat[1,] <- 1L:nc
desmat[,1] <- 1L:nr
desmat[nr,] <- nc:1L
desmat[,nc] <- nr:1L
carover <- matrix(0L,nrow=nr,ncol=nc)
for (i in 1L:(nc-1L)) carover[i+1,i] <- carover[i,i+1] <- 1L
desobject <- list(desmat=desmat,carover = carover)
desresult <- list()
addpoint(desobject,desresult)
}
nextpos <- function(desmat) which(is.na(desmat),arr.ind=TRUE)
checkdes <- function(desobject,row,col) {
# test for only once carry over
all(desobject$carover<=1) &
# each product only once in each row and each column
!any(desobject$desmat[row,-col]== desobject$desmat[row,col],na.rm=TRUE ) &
!any(desobject$desmat[-row,col]== desobject$desmat[row,col],na.rm=TRUE )
}
addpoint <- function(desobject,desresult) {
todo <- nextpos(desobject$desmat)
if (length(todo)==0) {
l <- length(desresult)
desresult[[l+1]] <- desobject$desmat
return(desresult)
}
row <- todo[1L,1L]
col <- todo[1L,2L]
nc <- ncol(desobject$desmat)
dob <- desobject
for (i in 1L:nc) {
desobject$desmat[row,col] <- i
desobject$desmat[nc-row+1,nc-col+1] <- i
desobject$carover[desobject$desmat[row,col-1L],i] <- desobject$carover[desobject$desmat[row,col-1],i] + 1L
desobject$carover[i,desobject$desmat[row,col-1L]] <- desobject$carover[i,desobject$desmat[row,col-1L]] + 1L
other <- desobject$desmat[row,col+1L]
if (!is.na(other)) {
desobject$carover[other,i] <- desobject$carover[other,i] + 1
desobject$carover[i,other] <- desobject$carover[i,other] + 1
}
if (checkdes(desobject,row,col)) desresult <- addpoint(desobject,desresult)
desobject <- dob
}
desresult
}
gendesign(6)
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