I have some code that I have inherited that generates a matrix of significance levels for pairwise comparisons from predicted means. Since the model includes data from multiple sites and treatments, but I only want to compare between genotypes within a treatment within a site, only a subset of the comparisons are meaningful.
Here's a dummy version of what is currently generated.
effect.nam <- expand.grid(site=c("A","B","C"), treat=c("low","high"), genotype=c("A1","B2")) labels <- paste(effect.nam[,1],effect.nam[,2],effect.nam[,3], sep=".") mat <-matrix(sample(c(T,F),144,replace=T),12,12) dimnames(mat) <- list(labels,labels)
Obviously in this situation the T/F are random. What I would like is to only see the the comparisons within a sites and treatment. It would be nice to also remove the self comparison. Ideally I want to return a dataframe in the form:
Site Treat Genotype1 Genotype2 Sig 1 A low A1 2 TRUE 2 A low A1 3 TRUE 3 A low B2 3 TRUE 4 A high A1 2 TRUE 5 A high A1 3 FALSE 6 A high B2 3 FALSE 7 B low A1 2 FALSE 8 B low A1 3 TRUE 9 B low B2 3 FALSE 10 B high A1 2 TRUE 11 B high A1 3 TRUE 12 B high B2 3 TRUE 13 C low A1 2 TRUE 14 C low A1 3 TRUE 15 C low B2 3 FALSE 16 C high A1 2 TRUE 17 C high B1 3 TRUE 18 C high A2 3 TRUE
I've made a few false starts, and if anyone had some quick pointers in the right direction it would be appreciated.
In the very useful answer Chase gave below, you can see that while the meaningless comparisons have been removed, each useful comparison is contained twice (genotype 1 vs genotype 2 and vice versa). I can't see how to easily remove these, since they're not really duplicates...
My apologies, I needed to alter
mat so that when Chase's solution is implemented,
int, as is the case in my real situation. I've made a couple of additions to the solution below, given here (adding a sorting column to avoid doubling up comparisons).
It works, which is great, but adding those columns seems awkward to me - is there a more elegant way?
mat.m <- melt(mat) mat.m[,c("site1", "treat1", "genotype1")] <- colsplit(mat.m$X1, "\\.", c("site1", "treat1", "genotype1")) mat.m[,c("site2", "treat2", "genotype2")] <- colsplit(mat.m$X2, "\\.", c("site2", "treat2", "genotype2")) str(mat.m) mat.m$genotype1sort <- mat.m$genotype1 mat.m$genotype2sort <- mat.m$genotype2 levels(mat.m$genotype1sort) <- c(1, 2) levels(mat.m$genotype2sort) <- c(1, 2) mat.m$genotype1sort <- as.numeric(levels(mat.m$genotype1sort))[mat.m$genotype1sort] mat.m$genotype2sort <- as.numeric(levels(mat.m$genotype2sort))[mat.m$genotype2sort] subset(mat.m, site1 == site2 & treat1 == treat2 & genotype1 != genotype2 & genotype1sort < genotype2sort, select = c("site1", "treat1", "genotype1", "genotype2", "value")) #----- site1 treat1 genotype1 genotype2 value 73 A low A1 B2 TRUE 86 B low A1 B2 TRUE 99 C low A1 B2 TRUE 112 A high A1 B2 TRUE 125 B high A1 B2 FALSE 138 C high A1 B2 FALSE