# Matlab test of independence

For 1,000,000 observations, I observed a discrete event, X, 3 times for the control group and 10 times for the test group.

I need to preform a Chi square test of independence in Matlab. This is how you would do it in r:

``````m <- rbind(c(3, 1000000-3), c(10, 1000000-10))
#      [,1]   [,2]
# [1,]    3 999997
# [2,]   10 999990
chisq.test(m)
``````

The r function returns chi-squared = 2.7692, df = 1, p-value = 0.0961.

What Matlab function should I use or create to do this?

-

Here is my own implementation that I use:

``````function [hNull pValue X2] = ChiSquareTest(o, alpha)
%#  CHISQUARETEST  Pearson's Chi-Square test of independence
%#
%#    @param o          The Contignecy Table of the joint frequencies
%#                      of the two events (attributes)
%#    @param alpha      Significance level for the test
%#    @return hNull     hNull = 1: null hypothesis accepted (independent)
%#                      hNull = 0: null hypothesis rejected (dependent)
%#    @return pValue    The p-value of the test (the prob of obtaining
%#                      the observed frequencies under hNull)
%#    @return X2        The value for the chi square statistic
%#

%# o:     observed frequency
%# e:     expected frequency
%# dof:   degree of freedom

[r c] = size(o);
dof = (r-1)*(c-1);

%# e = (count(A=ai)*count(B=bi)) / N
e = sum(o,2)*sum(o,1) / sum(o(:));

%# [ sum_r [ sum_c ((o_ij-e_ij)^2/e_ij) ] ]
X2 = sum(sum( (o-e).^2 ./ e ));

%# p-value needed to reject hNull at the significance level with dof
pValue = 1 - chi2cdf(X2, dof);
hNull = (pValue > alpha);

%# X2 value needed to reject hNull at the significance level with dof
%#X2table = chi2inv(1-alpha, dof);
%#hNull = (X2table > X2);

end
``````

And an example to illustrate:

``````t = [3 999997 ; 10 999990]
[hNull pVal X2] = ChiSquareTest(t, 0.05)

hNull =
1
pVal =
0.052203
X2 =
3.7693
``````

Note that the results are different from yours because `chisq.test` performs a correction by default, according to `?chisq.test`

correct: a logical indicating whether to apply continuity correction when computing the test statistic for 2x2 tables: one half is subtracted from all |O - E| differences.

Alternatively if you have the actual observations of the two events in question, you can use the CROSSTAB function which computes the contingency table and return the Chi2 and p-value measures:

``````X = randi([1 2],[1000 1]);
Y = randi([1 2],[1000 1]);
[t X2 pVal] = crosstab(X,Y)

t =
229   247
257   267
X2 =
0.087581
pVal =
0.76728
``````

the equivalent in R would be:

``````chisq.test(X, Y, correct = FALSE)
``````

Note: Both (MATLAB) approaches above require the Statistics Toolbox

-
Ah, ninja'd. +1 for the code! – Jonas Jul 28 '10 at 20:07
@Amro, How would you implement the `correct = true` for matlab? – Elpezmuerto Jul 28 '10 at 20:29
well according to the R documentation just subtract half from |O-E|, so use the following instead: `X2 = sum(sum( (abs(o-e)-0.5).^2 ./ e ));` but you will have to manually check that this correction is only applied for 2x2 tables: en.wikipedia.org/wiki/Yates%27_correction_for_continuity – Amro Jul 28 '10 at 20:37
@Amro...High Five! The correct works! – Elpezmuerto Jul 28 '10 at 20:53
To calculate the alternative likelihood-ratio G2 statistic, use G2 = 2*sum(sum(o .* log(o./e))); – Elpezmuerto Aug 25 '10 at 15:37

This function will test for independence using the Pearson chi-squared statistic and the Likelihood-Ratio statistic, along with calculating residuals. I know this can be vectorized further, but I am trying to show the math for each step.

``````function independenceTest(data)
df = (size(data,1)-1)*(size(data,2)-1); % Mean Degrees of Freedom
sd = sqrt(2*df);                        % Standard Deviation

u         = nan(size(data)); % Estimated expected frequencies
p         = nan(size(data)); % Values used to calculate chi-square
lr        = nan(size(data)); % Values used to calculate likelihood-ratio
residuals = nan(size(data)); % Residuals

rowTotals    = sum(data,1);
colTotals    = sum(data,2);
overallTotal = sum(rowTotals);

%% Calculate estimated expected frequencies
for r=1:1:size(data,1)
for c=1:1:size(data,2)
u(r,c) = (rowTotals(c) * colTotals(r)) / overallTotal;
end
end

%% Calculate chi-squared statistic
for r=1:1:size(data,1)
for c=1:1:size(data,2)
p(r,c) = (data(r,c) - u(r,c))^2 / u(r,c);
end
end
chi = sum(sum(p)); % Chi-square statistic

%% Calculate likelihood-ratio statistic
for r=1:1:size(data,1)
for c=1:1:size(data,2)
lr(r,c) = data(r,c) * log(data(r,c) / u(r,c));
end
end
G = 2 * sum(sum(lr)); % Likelihood-Ratio statisitc

%% Calculate residuals
for r=1:1:size(data,1)
for c=1:1:size(data,2)
numerator   = data(r,c) - u(r,c);
denominator = sqrt(u(r,c) * (1 - colTotals(r)/overallTotal) * (1 - rowTotals(c)/overallTotal));
residuals(r,c) = numerator / denominator;
end
end
``````
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Check out @Amro's code. He does the same calculations without looping, and thus more concisely. – Jonas Jul 28 '10 at 20:19