Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

i would like to know if someone could tell me how you plot something similar to this enter image description here with histograms of the sample generates from the code below under the two curves. Using R or Matlab but preferably R.

# bivariate normal with a gibbs sampler...

gibbs<-function (n, rho) 
  mat <- matrix(ncol = 2, nrow = n)
  x <- 0
  y <- 0
  mat[1, ] <- c(x, y)
  for (i in 2:n) {
    x <- rnorm(1, rho * y, (1 - rho^2))
    y <- rnorm(1, rho * x,(1 - rho^2))
    mat[i, ] <- c(x, y)

plot(bvn,col=1:10000,main="bivariate normal distribution",xlab="X",ylab="Y")
plot(bvn,type="l",main="bivariate normal distribution",xlab="X",ylab="Y")

hist(bvn[,1],40,main="bivariate normal distribution",xlab="X",ylab="")
hist(bvn[,2],40,main="bivariate normal distribution",xlab="Y",ylab="")

Thanks in advance

Best regards,


share|improve this question
The original Matlab code is located alongside the original file on Wikimedia. (Source: I created the graph) – bscan Nov 23 '15 at 21:11
up vote 9 down vote accepted

You could do it in Matlab programmatically.

This is the result:

Matlab plot


% Generate some data.
data = randn(10000, 2);

% Scale and rotate the data (for demonstration purposes).
data(:,1) = data(:,1) * 2;
theta = deg2rad(130);
data = ([cos(theta) -sin(theta); sin(theta) cos(theta)] * data')';

% Get some info.
m = mean(data);
s = std(data);
axisMin = m - 4 * s;
axisMax = m + 4 * s;

% Plot data points on (X=data(x), Y=data(y), Z=0)
plot3(data(:,1), data(:,2), zeros(size(data,1),1), 'k.', 'MarkerSize', 1);

% Turn on hold to allow subsequent plots.
hold on

% Plot the ellipse using Eigenvectors and Eigenvalues.
data_zeroMean = bsxfun(@minus, data, m);
[V,D] = eig(data_zeroMean' * data_zeroMean / (size(data_zeroMean, 1)));
[D, order] = sort(diag(D), 'descend');
D = diag(D);
V = V(:, order);
V = V * sqrt(D);
t = linspace(0, 2 * pi);
e = bsxfun(@plus, 2*V * [cos(t); sin(t)], m');
    e(1,:), e(2,:), ...
    zeros(1, nPointsEllipse), 'g-', 'LineWidth', 2);

maxP = 0;
for side = 1:2
    % Calculate the histogram.
    p = [0 hist(data(:,side), 20) 0];
    p = p / sum(p);
    maxP = max([maxP p]);
    dx = (axisMax(side) - axisMin(side)) / numel(p) / 2.3;
    p2 = [zeros(1,numel(p)); p; p; zeros(1,numel(p))]; p2 = p2(:);
    x = linspace(axisMin(side), axisMax(side), numel(p));
    x2 = [x-dx; x-dx; x+dx; x+dx]; x2 = max(min(x2(:), axisMax(side)), axisMin(side));

    % Calculate the curve.
    nPtsCurve = numel(p) * 10;
    xx = linspace(axisMin(side), axisMax(side), nPtsCurve);

    % Plot the curve and the histogram.
    if side == 1
        plot3(xx, ones(1, nPtsCurve) * axisMax(3 - side), spline(x,p,xx), 'r-', 'LineWidth', 2);
        plot3(x2, ones(numel(p2), 1) * axisMax(3 - side), p2, 'k-', 'LineWidth', 1);
        plot3(ones(1, nPtsCurve) * axisMax(3 - side), xx, spline(x,p,xx), 'b-', 'LineWidth', 2);
        plot3(ones(numel(p2), 1) * axisMax(3 - side), x2, p2, 'k-', 'LineWidth', 1);


% Turn off hold.
hold off

% Axis labels.

axis([axisMin(1) axisMax(1) axisMin(2) axisMax(2) 0 maxP * 1.05]);
grid on;
share|improve this answer

Create the dataframe with bvn <-,0.98)). Several 2d solutions in R:

1: A quick & dirty solution with the psych package:

scatter.hist(x=bvn$V1, y=bvn$V2, density=TRUE, ellipse=TRUE)

which results in:

enter image description here

2: A nice & pretty solution with ggplot2:

source_url("") # needed to create the 95% confidence ellipse

htop <- ggplot(data=bvn, aes(x=V1)) + 
  geom_histogram(aes(y=..density..), fill = "white", color = "black", binwidth = 2) + 
  stat_density(colour = "blue", geom="line", size = 1.5, position="identity", show_guide=FALSE) +
  scale_x_continuous("V1", limits = c(-40,40), breaks = c(-40,-20,0,20,40)) + 
  scale_y_continuous("Count", breaks=c(0.0,0.01,0.02,0.03,0.04), labels=c(0,100,200,300,400)) + 
  theme_bw() + theme(axis.title.x = element_blank())

blank <- ggplot() + geom_point(aes(1,1), colour="white") +
  theme(axis.ticks=element_blank(), panel.background=element_blank(), panel.grid=element_blank(),
        axis.text.x=element_blank(), axis.text.y=element_blank(), axis.title.x=element_blank(), axis.title.y=element_blank())

scatter <- ggplot(data=bvn, aes(x=V1, y=V2)) + 
  geom_point(size = 0.6) + stat_ellipse(level = 0.95, size = 1, color="green") +
  scale_x_continuous("label V1", limits = c(-40,40), breaks = c(-40,-20,0,20,40)) + 
  scale_y_continuous("label V2", limits = c(-20,20), breaks = c(-20,-10,0,10,20)) + 

hright <- ggplot(data=bvn, aes(x=V2)) + 
  geom_histogram(aes(y=..density..), fill = "white", color = "black", binwidth = 1) + 
  stat_density(colour = "red", geom="line", size = 1, position="identity", show_guide=FALSE) +
  scale_x_continuous("V2", limits = c(-20,20), breaks = c(-20,-10,0,10,20)) + 
  scale_y_continuous("Count", breaks=c(0.0,0.02,0.04,0.06,0.08), labels=c(0,200,400,600,800)) + 
  coord_flip() + theme_bw() + theme(axis.title.y = element_blank())

grid.arrange(htop, blank, scatter, hright, ncol=2, nrow=2, widths=c(4, 1), heights=c(1, 4))

which results in:

enter image description here

3: A compact solution with ggplot2:

source_url("") # needed to create the 95% confidence ellipse

ggplot(data=bvn, aes(x=V1, y=V2)) + 
  geom_point(size = 0.6) + 
  geom_rug(sides="t", size=0.05, col=rgb(.8,0,0,alpha=.3)) + 
  geom_rug(sides="r", size=0.05, col=rgb(0,0,.8,alpha=.3)) + 
  stat_ellipse(level = 0.95, size = 1, color="green") +
  scale_x_continuous("label V1", limits = c(-40,40), breaks = c(-40,-20,0,20,40)) + 
  scale_y_continuous("label V2", limits = c(-20,20), breaks = c(-20,-10,0,10,20)) + 

which results in:

enter image description here

share|improve this answer

R Implementation

Load library "car". We use only dataEllipse function to draw ellipse based on the percent of data (0.95 means 95% data falls within the ellipse).


gibbs<-function (n, rho) 
   mat <- matrix(ncol = 2, nrow = n)
   x <- 0
   y <- 0
   mat[1, ] <- c(x, y)
   for (i in 2:n) {
   x <- rnorm(1, rho * y, (1 - rho^2))
   y <- rnorm(1, rho * x,(1 - rho^2))
   mat[i, ] <- c(x, y)


Open a PDF Device:

OUTFILE <- "bivar_dist.pdf"


Set up the layout first

layout(matrix(c(2,0,1,3),2,2,byrow=TRUE), widths=c(3,1), heights=c(1,3), TRUE)

Make Scatterplot


The commented lines can be used to plot a scatter diagram without "car" package from where we use dataEllipse function

# plot(bvn[,2], bvn[,1], 
#      pch=".",cex = 1, col=1:length(bvn[,2]),
#      xlim=c(-0.6, 0.6),
#      ylim=c(-0.6,0.6),
#      xlab="X",
#      ylab="Y")
# grid(NULL, NULL, lwd = 2)

dataEllipse(bvn[,2], bvn[,1],
        levels = c(0.95),
        xlim=c(-0.6, 0.6),
        center.cex = 1

Plot histogram of X variable in the top row


          col="light blue",border="black",
     title(main = "Bivariate Normal Distribution")

Plot histogram of Y variable to the right of the scatterplot

     yhist <- hist(bvn[,1],


             col="light blue",
             ) = dev.cur())

Image Output is Below

select 50 and 95 % data within ellipses

      dataEllipse(bvn[,2], bvn[,1],
                  levels = c(0.5, 0.95),
                  col= 1:length(bvn[,2]),
                  xlim=c(-0.6, 0.6),
                  center.cex = 1
share|improve this answer
3d scatterplot from the package "scatterplot3d". #scatterplot3d(y = bvn[,1], x=bvn[,2], xlab="X", ylab="p(Y)", zlab="Z", axis = T, angle=-80, pch = 21, z.ticklabs=NULL) – Sathish Apr 6 '14 at 21:15

I must admit, I took this on as a challenge because I was looking for different ways to show other datasets. I have normally done something along the lines of the scatterhist 2D graphs shown in other answers, but I've wanted to try my hand at rgl for a while.

I use your function to generate the data

gibbs<-function (n, rho) {
    mat <- matrix(ncol = 2, nrow = n)
    x <- 0
    y <- 0
    mat[1, ] <- c(x, y)
    for (i in 2:n) {
        x <- rnorm(1, rho * y, (1 - rho^2))
        y <- rnorm(1, rho * x, (1 - rho^2))
        mat[i, ] <- c(x, y)
bvn <- gibbs(10000, 0.98)


I use rgl for the hard lifting, but I didn't know how to get the confidence ellipse without going to car. I'm guessing there are other ways to attack this.

library(rgl) # plot3d, quads3d, lines3d, grid3d, par3d, axes3d, box3d, mtext3d
library(car) # dataEllipse

Process the data

Getting the histogram data without plotting it, I then extract the densities and normalize them into probabilities. The *max variables are to simplify future plotting.

hx <- hist(bvn[,2], plot=FALSE)
hxs <- hx$density / sum(hx$density)
hy <- hist(bvn[,1], plot=FALSE)
hys <- hy$density / sum(hy$density)

## [xy]max: so that there's no overlap in the adjoining corner
xmax <- tail(hx$breaks, n=1) + diff(tail(hx$breaks, n=2))
ymax <- tail(hy$breaks, n=1) + diff(tail(hy$breaks, n=2))
zmax <- max(hxs, hys)

Basic scatterplot on the floor

The scale should be set to whatever is appropriate based on the distributions. Admittedly, the X and Y labels aren't placed beautifully, but that shouldn't be too hard to reposition based on the data.

## the base scatterplot
plot3d(bvn[,2], bvn[,1], 0, zlim=c(0, zmax), pch='.',
       xlab='X', ylab='Y', zlab='', axes=FALSE)

Histograms on the back walls

I couldn't figure out how to get them automatically plotted on a plane in the overall 3D render, so I had to make each rect manually.

## manually create each histogram
for (ii in seq_along(hx$counts)) {
    quads3d(hx$breaks[ii]*c(.9,.9,.1,.1) + hx$breaks[ii+1]*c(.1,.1,.9,.9),
            rep(ymax, 4),
            hxs[ii]*c(0,1,1,0), color='gray80')
for (ii in seq_along(hy$counts)) {
    quads3d(rep(xmax, 4),
            hy$breaks[ii]*c(.9,.9,.1,.1) + hy$breaks[ii+1]*c(.1,.1,.9,.9),
            hys[ii]*c(0,1,1,0), color='gray80')

Summary Lines

## I use these to ensure the lines are plotted "in front of" the
## respective dot/hist
bb <- par3d('bbox')
inset <- 0.02 # percent off of the floor/wall for lines
x1 <- bb[1] + (1-inset)*diff(bb[1:2])
y1 <- bb[3] + (1-inset)*diff(bb[3:4])
z1 <- bb[5] + inset*diff(bb[5:6])

## even with draw=FALSE, dataEllipse still pops up a dev, so I create
## a dummy dev and destroy it ... better way to do this?
de <- dataEllipse(bvn[,1], bvn[,2], draw=FALSE, levels=0.95)

## the ellipse
lines3d(de[,2], de[,1], z1, color='green', lwd=3)

## the two density curves, probability-style
denx <- density(bvn[,2])
lines3d(denx$x, rep(y1, length(denx$x)), denx$y / sum(hx$density), col='red', lwd=3)
deny <- density(bvn[,1])
lines3d(rep(x1, length(deny$x)), deny$x, deny$y / sum(hy$density), col='blue', lwd=3)


grid3d(c('x+', 'y+', 'z-'), n=10)
axes3d(edges=c('x-', 'y-', 'z+'))
outset <- 1.2 # place text outside of bbox *this* percentage
mtext3d('P(X)', edge='x+', pos=c(0, ymax, outset * zmax))
mtext3d('P(Y)', edge='y+', pos=c(xmax, 0, outset * zmax))

Final Product

One bonus of using rgl is that you can spin it around with your mouse and find the best perspective. Lacking making an animation for this SO page, doing all of the above should allow you the play-time. (If you spin it, you'll be able to see that the lines are slightly in front of the histograms and slightly above the scatterplot; otherwise I found intersections, so it looked noncontinuous at places.)

3D bivariate scatter/hist

In the end, I find this a bit distracting (the 2D variants sufficed): showing the z-axis implies that there is a third dimension to the data; Tufte specifically discourages this behavior (Tufte, "Envisioning Information," 1990). However, with higher dimensionality, this technique of using RGL will allow significant perspective on patterns.

(For the record, Win7 x64, tested with R-3.0.3 in 32-bit and 64-bit, rgl v0.93.996, car v2.0-19.)

share|improve this answer

Matlab's implementation is called scatterhist and requires the Statistics Toolbox. Unfortunately it is not 3D, it is an extended 2D plot.

% some example data
x = randn(1000,1);
y = randn(1000,1);

h = scatterhist(x,y,'Location','SouthEast',...

legend boxoff
grid on

enter image description here

It also allows grouping of datasets:

load fisheriris.mat;
x = meas(:,1);        %// x-data
y = meas(:,2);        %// y-data
gnames = species;     %// assigning of names to certain elements of x and y


enter image description here

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.