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I'm trying to get a fine-grain visualisation of critical values I got from posthoc Tukey. There are some good guidelines out there for visualizing pairwise comparisons, but I need something more refined. The idea is that I would have a plot where each small square would represent a critical value from the matrix below, coded in such manner that:

  • if the value is higher or equal to 5.45 - it's a black square;
  • if the value is lower or equal to -5.45 - it's a gray square;
  • if the value is between -5.65 and 5.65 - it's a white square.

The data matrix is here.

Or maybe you would have better suggestion how to visualize those critical values?

EDIT: Following comments from @Aaron and @DWin I want to provide a bit more context for the above data and justification for my question. I am looking at the mean ratings of acceptability for seven virtual characters, each of them is animated on 5 different levels. So, I have two factors there - character (7 levels) and motion (5 levels). Because I have found interaction between those two factors, I decided to look at differences between the means for all the characters for all levels of motion , which resulted in this massive matrix, as an output of posthoc Tukey. It's probably too much detail now, but please don't throw me out to Cross Validated, they will eat me alive...

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A better suggestion would depend on what story you're trying to tell with this data. Normally one sorts the levels by their mean value, but it appears you may have patterns in the levels that have some special meaning; in particular, it seems that every five may be related (or not) in some particular way. I'm also wary of visualizing critical values as that's a measure of statistical significance and so hides the practical significance (or lack thereof) of your results. –  Aaron Dec 6 '11 at 3:05
2  
C'mon, you can do it! Post your first Cross Validated question... I triple-dog-dare you! (Really, we're not that much scarier over there.) Just explain your data, what you want to know, and most importantly, why you want to know it. You don't have to have an answer yet; that's why you're asking the question. –  Aaron Dec 6 '11 at 4:24
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4 Answers

up vote 5 down vote accepted

This is fairly straightforward with image:

d <- as.matrix(read.table("http://dl.dropbox.com/u/2505196/postH.dat"))    
image(x=1:35, y=1:35, as.matrix(d), breaks=c(min(d), -5.45, 5.45, max(d)), 
      col=c("grey", "white", "black"))

For just half, set half to missing with d[upper.tri(d)] <- NA and add na.rm=TRUE to the min and max functions.

enter image description here

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I am totally digging image function, thanks. R is so incredible... –  Geek On Acid Dec 7 '11 at 1:12
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Here is a ggplot2 solution. I'm sure there are simpler ways to accomplish this -- I guess I got carried away!

library(ggplot2)

# Load data.
postH = read.table("~/Downloads/postH.dat")
names(postH) = paste("item", 1:35, sep="") # add column names.
postH$item_id_x = paste("item", 1:35, sep="") # add id column.

# Convert data.frame to long form.
data_long = melt(postH, id.var="item_id_x", variable_name="item_id_y")

# Convert to factor, controlling the order of the factor levels.
data_long$item_id_y = factor(as.character(data_long$item_id_y), 
                        levels=paste("item", 1:35, sep=""))
data_long$item_id_x = factor(as.character(data_long$item_id_x), 
                        levels=paste("item", 1:35, sep=""))

# Create critical value labels in a new column.
data_long$critical_level = ifelse(data_long$value >= 5.45, "high",
                             ifelse(data_long$value <= -5.65, "low", "middle"))

# Convert to labels to factor, controlling the order of the factor levels.
data_long$critical_level = factor(data_long$critical_level,
                                  levels=c("high", "middle", "low"))

# Named vector for ggplot's scale_fill_manual
critical_level_colors = c(high="black", middle="grey80", low="white")

# Calculate grid line positions manually.
x_grid_lines = seq(0.5, length(levels(data_long$item_id_x)), 1)
y_grid_lines = seq(0.5, length(levels(data_long$item_id_y)), 1)

# Create plot.
plot_1 = ggplot(data_long, aes(xmin=as.integer(item_id_x) - 0.5,
                               xmax=as.integer(item_id_x) + 0.5,
                               ymin=as.integer(item_id_y) - 0.5,
                               ymax=as.integer(item_id_y) + 0.5,
                               fill=critical_level)) +
     theme_bw() +
     opts(panel.grid.minor=theme_blank(), panel.grid.major=theme_blank()) +
     coord_cartesian(xlim=c(min(x_grid_lines), max(x_grid_lines)),
                     ylim=c(min(y_grid_lines), max(y_grid_lines))) +
     scale_x_continuous(breaks=seq(1, length(levels(data_long$item_id_x))),
                        labels=levels(data_long$item_id_x)) +
     scale_y_continuous(breaks=seq(1, length(levels(data_long$item_id_x))),
                        labels=levels(data_long$item_id_y)) +
     scale_fill_manual(name="Critical Values", values=critical_level_colors) +
     geom_rect() +
     geom_hline(yintercept=y_grid_lines, colour="grey40", size=0.15) +
     geom_vline(xintercept=x_grid_lines, colour="grey40", size=0.15) +
     opts(axis.text.y=theme_text(size=9)) +
     opts(axis.text.x=theme_text(size=9, angle=90)) +
     opts(title="Critical Values Matrix")

# Save to pdf file.
pdf("plot_1.pdf", height=8.5, width=8.5)
print(plot_1)
dev.off()

enter image description here

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Wow that really is MASSIVE solution @bdemarest but thank you very much for an effort. Excellent code description as well. One question - how would you display only half of this matrix, cutting it diagonally? –  Geek On Acid Dec 6 '11 at 1:18
    
@Geek On Acid: I've pondered this for a while, and I don't see an easy way to do that. It seems that my solution is not very general/customizable! Maybe someone else has thoughts on this... –  bdemarest Dec 6 '11 at 2:47
    
Couldn't you use ggfluctuation() instead? –  chl Dec 6 '11 at 16:07
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If you set this up with findInterval as an index into the bg, col, and/or pch arguments (although they are all squares at the moment), you should find the code fairly compact and understandable.

You'll need to get the data in long format first; here's one way:

d <- as.matrix(read.table("http://dl.dropbox.com/u/2505196/postH.dat"))
dat <- within(as.data.frame(as.table(d)), 
              { Var1 <- as.numeric(Var1)  
                Var2 <- as.numeric(Var2) })

Then the code is as follows; pch=22 uses filled squares, bg sets the fill color of the square, col sets the border color, and cex=1.5 just makes them a little bigger than the default.

plot(dat$Var1, dat$Var2, 
     bg = c("grey", "white", "black")[1+findInterval(dat$Freq, c(-5.45,5.45))],
     col="white", cex=1.5, pch = 22)

You need the 1+ in there because the values would be 0,1,2 and your indices need to start with 1.

enter image description here

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mind if I edit to add the resulting picture (with slightly modified code?) –  Aaron Dec 6 '11 at 2:53
    
@Aaron: Hack on. –  BondedDust Dec 6 '11 at 4:34
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To make a closure here I used majority of suggestions from @DWin and @Aaron to create the plot below. The lightest level of gray stands for non-significant values. I also used rect to create lines above axis names to better differentiate between conditions:

d <- as.matrix(read.table("http://dl.dropbox.com/u/2505196/postH.dat"))
#remove upper half of the values (as they are mirrored values)
d[upper.tri(d)] <- NA
dat <- within(as.data.frame(as.table(d)),{
Var1 <- as.numeric(Var1)
Var2 <- as.numeric(Var2)})
par(mar=c(6,3,3,6))
colPh=c("gray50","gray90","black")
plot(dat$Var1,dat$Var2,bg = colPh[1+findInterval(dat$Freq, c(-5.45,5.45))],
    col="white",cex=1.2,pch = 21,axes=F,xlab="",ylab="")
labDis <- rep(c("A","B","C","D","E"),times=7)
labChar <- c(1:7)
axis(1,at=1:35,labels=labDis,cex.axis=0.5,tick=F,line=-1.4)
axis(1,at=seq(3,33,5),labels=labChar, tick=F)
#drawing lines above axis for better identification
rect(1,0,5,0,angle=90);rect(6,0,10,0,angle=90);rect(11,0,15,0,angle=90);
rect(16,0,20,0,angle=90);rect(21,0,25,0,angle=90);rect(26,0,30,0,angle=90);
rect(31,0,35,0,angle=90)
axis(4,at=1:35,labels=labDis,cex.axis=0.5,tick=F,line=-1.4)
axis(4,at=seq(3,33,5),labels=labChar,tick=F)
#drawing lines above axis for better identification
rect(36,1,36,5,angle=90);rect(36,6,36,10,angle=90);rect(36,11,36,15,angle=90);
rect(36,16,36,20,angle=90);rect(36,21,36,25,angle=90);rect(36,26,36,30,angle=90);
rect(36,31,36,35,angle=90)
legend("topleft",legend=c("not significant","p<0.01","p<0.05"),pch=16,
col=c("gray90","gray50","black"),cex=0.7,bty="n")

enter image description here

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