I wonder how one can add another layer of important and needed complexity to a matrix correlation heatmap like for example the p value after the manner of the significance level stars in addition to the R2 value (-1 to 1)?
It was NOT INTENDED in this question to put significance level stars OR the p values as text on each square of the matrix BUT rather to show this in a graphical out-of-the-box representation of significance level on each square of the matrix. I think only those who enjoy the blessing of INNOVATIVE thinking can win the applause to unravel this kind of solution in order to have the best way to represent that added component of complexity to our "half-of-the-truth matrix correlation heatmaps". I googled a lot but never seen a proper or I shall say an "eye-friendly" way to represent the significance level PLUS the standard color shades that reflect the R coefficient.
The reproducible data set is found here:
The R code please find below:

library(plyr) # might be not needed here anyway it is a must-have package I think in R 
library(reshape2) # to "melt" your dataset
library (scales) # it has a "rescale" function which is needed in heatmaps 
library(RColorBrewer) # for convenience of heatmap colors, it reflects your mood sometimes
nba <- read.csv("http://datasets.flowingdata.com/ppg2008.csv")
nba <- as.data.frame(cor(nba[2:ncol(nba)])) # convert the matrix correlations to a dataframe 
nba.m <- data.frame(row=rownames(nba),nba) # create a column called "row"
rownames(nba) <- NULL #get rid of row names
nba <- melt(nba)
nba.m$value<-cut(nba.m$value,breaks=c(-1,-0.75,-0.5,-0.25,0,0.25,0.5,0.75,1),include.lowest=TRUE,label=c("(-0.75,-1)","(-0.5,-0.75)","(-0.25,-0.5)","(0,-0.25)","(0,0.25)","(0.25,0.5)","(0.5,0.75)","(0.75,1)")) # this can be customized to put the correlations in categories using the "cut" function with appropriate labels to show them in the legend, this column now would be discrete and not continuous
nba.m$row <- factor(nba.m$row, levels=rev(unique(as.character(nba.m$variable)))) # reorder the "row" column which would be used as the x axis in the plot after converting it to a factor and ordered now
#now plotting
ggplot(nba.m, aes(row, variable)) +
geom_tile(aes(fill=value),colour="black") +
scale_fill_brewer(palette = "RdYlGn",name="Correlation")  # here comes the RColorBrewer package, now if you ask me why did you choose this palette colour I would say look at your battery charge indicator of your mobile for example your shaver, won't be red when gets low? and back to green when charged? This was the inspiration to choose this colour set.

The matrix correlation heatmap should look like this:
enter image description here

Hints and ideas to enhance the solution:
- This code might be useful to have an idea about the significance level stars taken from this website:
R code:

mystars <- ifelse(p < .001, "***", ifelse(p < .01, "** ", ifelse(p < .05, "* ", " "))) # so 4 categories  

- The significance level can be added as colour intensity to each square like alpha aesthetics but I don't think this will be easy to interpret and to capture
- Another idea would be to have 4 different sizes of squares corresponding to the stars, of course giving the smallest to the non significant and increases to a full size square if highest stars
- Another idea to include a circle inside those significant squares and the thickness of the line of the circle corresponds to the level of significance (the 3 remaining categories) all of them of one colour
- Same as above but fixing the line thickness while giving 3 colours for the 3 remaining significant levels
- May be you come up with better ideas, who knows?

  • 2
    Your code inspired me to rewrite the arm::corrplot function with ggplot2: rpubs.com/briatte/ggcorr
    – Fr.
    Mar 17, 2013 at 21:02
  • it works great! can you please extend this function to cause those non-significant correlations (e.g.<0.05) disappear, while keeping those equal or above. Here, one should feed the function with another matrix BUT with p values, I share with you this function which can be of help to get that p matrix (you can use : cor.prob.all() cor.prob.all <- function (X, dfr = nrow(X) - 2) { R <- cor(X, use="pairwise.complete.obs",method="spearman") r2 <- R^2 Fstat <- r2 * dfr/(1 - r2) R<- 1 - pf(Fstat, 1, dfr) R[row(R) == col(R)] <- NA R }
    – doctorate
    Mar 18, 2013 at 14:53
  • Thanks for your feedback. I am skeptical about the use of $p$-values here (and elsewhere), but I will try to work out something to flag insignificant coefficients.
    – Fr.
    Mar 19, 2013 at 12:42
  • The function cited above is now part of the GGally package, with corrections and additions by the maintainer of the package.
    – Fr.
    Apr 14, 2013 at 23:08
  • Where is the (-1, -0,75) color ?? With c(-1,-0.75,-0.5,-0.25,0,0.25,0.5,0.75,1), we should have 8 interval and 8 colors, not 7...
    – Gildas
    Mar 14, 2018 at 11:42

3 Answers 3


This is just an attempt to enhance towards the final solution, I plotted the stars here as indicator of the solution, but as I said the aim is to find a graphical solution that can speak better than the stars. I just used geom_point and alpha to indicate significance level but the problem that the NAs (that includes the non-significant values as well) will show up like that of three stars level of significance, how to fix that? I think that using one colour might be more eye-friendly when using many colors and to avoid burdening the plot with many details for the eyes to resolve. Thanks in advance.
Here is the plot of my first attempt:
enter image description here

or might be this better?!
enter image description here

I think the best till now is the one below, until you come up with something better ! enter image description here

As requested, the below code is for the last heatmap:

# Function to get the probability into a whole matrix not half, here is Spearman you can change it to Kendall or Pearson
cor.prob.all <- function (X, dfr = nrow(X) - 2) {
R <- cor(X, use="pairwise.complete.obs",method="spearman")
r2 <- R^2
Fstat <- r2 * dfr/(1 - r2)
R<- 1 - pf(Fstat, 1, dfr)
R[row(R) == col(R)] <- NA
# Change matrices to dataframes
nbar<- as.data.frame(cor(nba[2:ncol(nba)]),method="spearman") # to a dataframe for r^2
nbap<- as.data.frame(cor.prob.all(nba[2:ncol(nba)])) # to a dataframe for p values
# Reset rownames
nbar <- data.frame(row=rownames(nbar),nbar) # create a column called "row" 
rownames(nbar) <- NULL
nbap <- data.frame(row=rownames(nbap),nbap) # create a column called "row" 
rownames(nbap) <- NULL
# Melt
nbar.m <- melt(nbar)
nbap.m <- melt(nbap)
# Classify (you can classify differently for nbar and for nbap also)         
nbar.m$value2<-cut(nbar.m$value,breaks=c(-1,-0.75,-0.5,-0.25,0,0.25,0.5,0.75,1),include.lowest=TRUE, label=c("(-0.75,-1)","(-0.5,-0.75)","(-0.25,-0.5)","(0,-0.25)","(0,0.25)","(0.25,0.5)","(0.5,0.75)","(0.75,1)")) # the label for the legend
nbap.m$value2<-cut(nbap.m$value,breaks=c(-Inf, 0.001, 0.01, 0.05),label=c("***", "** ", "*  ")) 
nbar.m<-cbind.data.frame(nbar.m,nbap.m$value,nbap.m$value2) # adding the p value and its cut to the first dataset of R coefficients
names(nbar.m)[5]<-paste("valuep") # change the column names of the dataframe 
nbar.m$row <- factor(nbar.m$row, levels=rev(unique(as.character(nbar.m$variable)))) # reorder the variable factor
# Plotting the matrix correlation heatmap
# Set options for a blank panel
po.nopanel <-list(theme(panel.background=theme_blank(),panel.grid.minor=theme_blank(),panel.grid.major=theme_blank()))
pa<-ggplot(nbar.m, aes(row, variable)) +
geom_tile(aes(fill=value2),colour="white") +
scale_fill_brewer(palette = "RdYlGn",name="Correlation")+ # RColorBrewer package
pa # check the first plot
# Adding the significance level stars using geom_text 
pp<- pa +
geom_text(aes(label=signif.),size=2,na.rm=TRUE) # you can play with the size
# Workaround for the alpha aesthetics if it is good to represent significance level, the same workaround can be applied for size aesthetics in ggplot2 as well. Applying the alpha aesthetics to show significance is a little bit problematic, because we want the alpha to be low while the p value is high, and vice verse which can't be done without a workaround
nbar.m$signif.<-rescale(as.numeric(nbar.m$signif.),to=c(0.1,0.9)) # I tried to use to=c(0.1,0.9) argument as you might expect, but to avoid problems with the next step of reciprocal values when dividing over one, this is needed for the alpha aesthetics as a workaround
nbar.m$signif.<-as.factor(0.09/nbar.m$signif.) # the alpha now behaves as wanted  except for the NAs values stil show as if with three stars level, how to fix that?
# Adding the alpha aesthetics in geom_point in a shape of squares (you can improve here)
pp<- pa +
geom_point(data=nbar.m,aes(alpha=signif.),shape=22,size=5,colour="darkgreen",na.rm=TRUE,legend=FALSE) # you can remove this step, the result of this step is seen in one of the layers in the above green heatmap, the shape used is 22 which is again a square but the size you can play with it accordingly  

I hope that this can be a step forward to reach there! Please note:

  • Some suggested to classify or cut the R^2 differently, ok we can do that of course but still we want to show the audience GRAPHICALLY the significance level instead of troubling the eye with the star levels. Can we ACHIEVE that in principle or not?
  • Some suggested to cut the p values differently, Ok this can be a choice after failure of showing the 3 levels of significance without troubling the eye. Then it might be better to show significant/non-significant without levels
  • There might be a better idea you come up with for the above workaround in ggplot2 for alpha and size aesthetics, hope to hear from you soon !
  • The question is not answered yet, waiting for an innovative solution !
  • Interestingly, "corrplot" package does it! I came up with this graph below by this package, PS: the crossed squares are not significant ones, level of signif=0.05. But how can we translate this to ggplot2, can we?!

enter image description here

-Or you can do circles and hide those non-significant? how to do this in ggplot2?!
enter image description here

  • 1
    fantastic plots, but people should be aware that a p-value may not mean what they expect (or anything) in this context of a correlation coefficient heatmap. If you've got this many possible correlations ($n^2-n/2$), p values of even >.99 actually start to become somewhat likely. Relying overly on p-values in this context may be considered p-hacking by another name. This xkcd explains it beautifully.
    – maxheld
    Dec 17, 2018 at 15:56
  • opts() has been deprecated a long time ago. Use theme() options. Nov 10, 2019 at 21:03
nba <- as.matrix(read.csv("https://raw.githubusercontent.com/Shicheng-Guo/Shicheng-Guo.Github.io/master/data/ppg2008.csv")[-1])
res1 <- cor.mtest(nba, conf.level = .95)

# correlation and P-value
corrplot(cor(nba), p.mat = res1$p, insig = "label_sig",sig.level = c(.001, .01, .05), pch.cex = 0.8, pch.col = "white",tl.cex=0.8)

# correlation and hclust
corrplot(cor(nba), method = "shade", outline = T, addgrid.col = "darkgray", order="hclust", 
         mar = c(4,0,4,0), addrect = 4, rect.col = "black", rect.lwd = 5,cl.pos = "b", tl.col = "indianred4", 
         tl.cex = 0.8, cl.cex = 0.8)

To signify significance along the estimated correlation coefficients you could vary the amount of coloring - either using alpha or by filling only a subset of each tile:

# install.packages("fdrtool")
# install.packages("data.table")

#download dataset
nba <- as.matrix(read.csv("http://datasets.flowingdata.com/ppg2008.csv")[-1])
m <- ncol(nba)
# compute corellation and p.values for all combinations of columns
dt <- CJ(i=seq_len(m), j=seq_len(m))[i<j]
dt[, c("p.value"):=(cor.test(nba[,i],nba[,j])$p.value), by=.(i,j)]
dt[, c("corr"):=(cor(nba[,i],nba[,j])), by=.(i,j)]

# estimate local false discovery rate
dt[,lfdr:=fdrtool::fdrtool(p.value, statistic="pvalue")$lfdr]

dt <- rbind(dt, setnames(copy(dt),c("i","j"),c("j","i")), data.table(i=seq_len(m),j=seq_len(m), corr=1, p.value=0, lfdr=0))

#use alpha
ggplot(dt, aes(x=i,y=j, fill=corr, alpha=1-lfdr)) + 
  scale_fill_distiller(palette = "RdYlGn", direction=1, limits=c(-1,1),name="Correlation") +
  scale_x_continuous("variable", breaks = seq_len(m), labels = colnames(nba)) +
  scale_y_continuous("variable", breaks = seq_len(m), labels = colnames(nba), trans="reverse") +
  coord_fixed() +
  theme(axis.text.x=element_text(angle=90, vjust=0.5),


#use area
ggplot(dt, aes(x=i,y=j, fill=corr,  height=sqrt(1-lfdr),  width=sqrt(1-lfdr))) + 
  scale_fill_distiller(palette = "RdYlGn", direction=1, limits=c(-1,1),name="Correlation") +
  scale_color_distiller(palette = "RdYlGn", direction=1, limits=c(-1,1),name="Correlation") +
  scale_x_continuous("variable", breaks = seq_len(m), labels = colnames(nba)) +
  scale_y_continuous("variable", breaks = seq_len(m), labels = colnames(nba), trans="reverse") +
  coord_fixed() +
  theme(axis.text.x=element_text(angle=90, vjust=0.5),


Key here is the scaling of the p.values: In order to obtain easy-to-interpret values that show large variation only in relevant regions, I use estimates of upper bound for the local false discovery (lfdr) provided by fdrtools instead. I.e, the alpha value of an tile is likely smaller or equal to the probability of that correlation to be different from 0.

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