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How to normalize a histogram, so it is a probability density (how is that the sum of all bins are equal to 1?).

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didn't you just ask this questions yesterday? How come you accepted there an answer if it didn't answer your question? (BTW, I think the answer there is correct, rather this answer you accepted here). Please try to clarify what you are really looking for. For detailed questions you may consider to ask them in Thanks – eat Mar 16 '11 at 6:10
up vote 94 down vote accepted

My answer to this is the same as in an answer to your earlier question. For a probability density function, the integral over the entire space is 1. Dividing by the sum will not give you the correct density. To get the right density, you must divide by the area. To illustrate my point, try the following example.

[f,x]=hist(randn(10000,1),50);%# create histogram from a normal distribution.
g=1/sqrt(2*pi)*exp(-0.5*x.^2);%# pdf of the normal distribution

bar(x,f/sum(f));hold on
plot(x,g,'r');hold off

bar(x,f/trapz(x,f));hold on
plot(x,g,'r');hold off

You can see for yourself which method agrees with the correct answer (red curve).

enter image description here

Another Method (more straight forward than Method 2) to normalize the histogram is divide by "sum(f*dx)" which expresses the integral of the prob density function. I.e.

dx = diff(x(1:2))
bar(x,f/sum(f*dx));hold on
plot(x,g,'r');hold off
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The sum of the "Divide by area figure" doesn't equal 1. I see at least 10 bar plot points greater than 0.3. 0.3*10 = 3.0 Wouldn't a simpler solution be to divide f by the # of samples? In this case, 10000. – Rich Mar 3 '14 at 23:39
@Rich The bars are thinner than 1, so your calculation is wrong. Consider the triangle unter the curve from (-2,0) to (0, 0.4) to (2, 0) to estimate the area. This triangle has an area of 0.5*4*0.4 = 0.8 < 1.0 – neingeist May 21 '14 at 9:50
to get the sum equal to 1, you need to multiply the new sum of bins by the width of the bin – Intendia Nov 7 '15 at 18:56

hist can not only plot an histogram but also return you the count of elements in each bin, so you can get that count, normalize it by dividing each bin by the total and plotting the result using bar. Example:

Y = rand(10,1);
C = hist(Y);
C = C ./ sum(C);

or if you want a one-liner:

bar(hist(Y) ./ sum(hist(Y)))


Edit: This solution answers the question How to have the sum of all bins equal to 1. This approximation is valid only if your bin size is small relative to the variance of your data. The sum used here correspond to a simple quadrature formula, more complex ones can be used like trapz as proposed by R. M.

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the one-liner is great :) – Vass Mar 20 '13 at 16:57

The area for each individual bar is height*width. Since MATLAB will choose equidistant points for the bars, so the width is:

delta_x = x(2) - x(1)

Now if we sum up all the individual bars the total area will come out as


So the correctly scaled plot is obtained by

bar(x, f/sum(f)/(x(2)-x(1)))
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Since 2014b, Matlab has these normalization routines embedded natively in the histogram function (see the help file for the 6 routines this function offers). Here is an example using the PDF normalization (the sum of all the bins is 1).

x = 2*randn(5000,1) + 5;             % generate normal random (m=5, std=2)
histogram(x,'Normalization','pdf')   % PDF normalization

The corresponding PDF is

y = -5:0.1:15;
mu = 5;
sigma = 2;
f = exp(-(y-mu).^2./(2*sigma^2))./(sigma*sqrt(2*pi));

The two together gives

hold on;

enter image description here

An improvement that might very well be due to the success of the actual question and accepted answer!

EDIT - The use of hist and histc is not recommended now, and histogram should be used instead. Beware that none of the 6 ways of creating bins with this new function will produce the bins hist and histc produce. There is a Matlab script to update former code to fit the way histogram is called (bin edges instead of bin centers - link). By doing so, one can compare the pdf normalization methods of @abcd (trapz and sum) and Matlab (pdf).

The 3 pdf normalization method give nearly identical results (within the range of eps).


A = randn(10000,1);
centers = -6:0.5:6;
d = diff(centers)/2;
edges = [centers(1)-d(1), centers(1:end-1)+d, centers(end)+d(end)];
edges(2:end) = edges(2:end)+eps(edges(2:end));

title('HIST not normalized');

h = histogram(A,edges);
title('HISTOGRAM not normalized');

[counts, centers] = hist(A,centers); %get the count with hist
title('HIST with PDF normalization');

h = histogram(A,edges,'Normalization','pdf')
title('HISTOGRAM with PDF normalization');

dx = diff(centers(1:2))
normalization_difference_trapz = abs(counts/trapz(centers,counts) - h.Values);
normalization_difference_sum = abs(counts/sum(counts*dx) - h.Values);


enter image description here

The maximum difference between the new PDF normalization and the former one is 5.5511e-17.

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For some Distributions, Cauchy I think, I have found that trapz will overestimate the area, and so the pdf will change depending on the number of bins you select. In which case I do

[N,h]=hist(q_f./theta,30000); % there Is a large range but most of the bins will be empty
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There is an excellent three part guide for Histogram Adjustments in MATLAB, the first part is on Histogram Stretching.

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