# Generate and plot the empirical joint pdf and CDF [closed]

Given a pair of two variables (X,Y), how can you generate and plot the empirical joint PDF and CDF in vanilla MATLAB (no toolboxes)?

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What do you mean by "empirical joint pdf" ? –  Nick Sep 5 '13 at 14:53
ok, so I used google: empirical joint probability density function! –  Nick Sep 5 '13 at 14:56
how are these variables related? I think we need more information here. –  MZimmerman6 Sep 5 '13 at 15:19
@MZimmerman6 The statistical relationship between the variables doesn't need to be known in advance; rather, will be a result that can be observed from the computed PDF and CDF –  Luis Mendo Sep 5 '13 at 16:34
right, I do not know what I was thinking. nevermind disregard my comment –  MZimmerman6 Sep 5 '13 at 18:08

## closed as off-topic by Oleg Komarov, John Kraft, Phillip Cloud, Adrian Wragg, allprogSep 5 '13 at 21:24

This question appears to be off-topic. The users who voted to close gave this specific reason:

• "Questions asking for code must demonstrate a minimal understanding of the problem being solved. Include attempted solutions, why they didn't work, and the expected results. See also: Stack Overflow question checklist" – Oleg Komarov, John Kraft, Phillip Cloud, Adrian Wragg
If this question can be reworded to fit the rules in the help center, please edit the question.

The data are:

• The random variables X, Y: defined as vectors of samples `X`, `Y`.
• The bin edges at the x, y axes: defined by vectors `x_axis`, `y_axis`. The edges must obviously be increasing, but need not be uniformly spaced.

The resulting PDF and CDF are defined at the centers of the rectangles determined by the x and y edges.

To plot the results in 3D, use `surf(...)` instead of `imagesc(...)`.

``````clear all

% Data (example):
X = randn(1,1e5); % random variables.
Y = randn(1,1e5);

x_axis = -3:.2:3; % Define edges of bins for x axis. Column vector
y_axis = -3:.2:3; % Same for y axis

% Compute corners of 2D-bins:
[x_mesh_upper,y_mesh_upper] = meshgrid(x_axis(2:end),y_axis(2:end));
[x_mesh_lower,y_mesh_lower] = meshgrid(x_axis(1:end-1),y_axis(1:end-1));

% Compute centers of 1D-bins:
x_centers = (x_axis(2:end)+x_axis(1:end-1))/2;
y_centers = (y_axis(2:end)+y_axis(1:end-1))/2;

% Compute pdf:
pdf = mean( bsxfun(@le, X(:), x_mesh_upper(:).') ...
& bsxfun(@gt, X(:), x_mesh_lower(:).') ...
& bsxfun(@le, Y(:), y_mesh_upper(:).') ...
& bsxfun(@gt, Y(:), y_mesh_lower(:).') );
pdf = reshape(pdf,length(x_axis)-1,length(y_axis)-1); % pdf values at the
% grid points defined by x_centers, y_centers
pdf = pdf ./ (y_mesh_upper-y_mesh_lower) ./ (x_mesh_upper-x_mesh_lower);
% normalize pdf to unit integral

% Compute cdf:
cdf = mean( bsxfun(@le, X(:), x_mesh_upper(:).') ...
& bsxfun(@le, Y(:), y_mesh_upper(:).') );
cdf = reshape(cdf,length(x_axis)-1,length(y_axis)-1);

% Plot pdf
figure
imagesc(x_centers,y_centers,pdf)
axis xy
axis equal
colorbar
title 'pdf'

% Plot cdf
figure
imagesc(x_centers,y_centers,cdf)
axis xy
axis equal
colorbar
title 'cdf'
``````

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