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I'm working with a set of data and I've obtained a certain correlations (using pearson's correlation coefficient). I've been asked to determine the "quality of the correlation," and by that my supervisor means he wants to see what the correlations would be if I tried permuting all the y values of my ordered pairs, and compared the obtained correlation coefficients. Does anyone know a nice way of doing this? Is there a matlab function that would determine how good a correlation is when compared to a correlation between random permutations of the data?

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3 Answers 3

First, you have to check whether the correlation coefficient you got is significantly different from zero. The corr function can do this (see pval).

Second, if it's significantly different from zero, then you would like to decide whether this difference is also significant from a practical point of view. In practice, the square of the correlation coefficent (the coefficient of determination) is considered significant, if it's larger than 0.5, which means that the variations of one of the correlated parameters "explains" at least 50% of the variation of the other.

Third, there are cases when the coefficient of determination is close to one, but this is not enough to determine the "goodness of correlation". For example, if you measure the same variable using two different methods, you will usually get very similar values, so the correlation coefficient will be almost 1. In such cases you should apply the Bland-Altman analysis, which is very easy to implement in Matlab, and has its own "goodness" parameters (the bias and the so-called limits of agreement).

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You can permute one vector's labels N times and calculate coefficient of correlations (cc) for each iteration. Then you can compare distribution of those values with the real correlation.

Something like this:

%# random data
n = 20;
x = (1:n)';
y = x + randn(n,1)*3;

%# real correlation
cc = corr(x,y);

%# do permutations
n_iter = 100; %# number of permutations
cc_iter = zeros(n_iter,1); %# preallocate the vector
for k = 1:n_iter
    ind = randperm(n); %# vector of random permutations
    cc_iter(k) = corr(x,y(ind));
end

%# calculate statistics
cc_mean = mean(cc_iter);
cc_std = std(cc_iter);
zval = cc - cc_mean ./ cc_std;
%# probability that the real cc belongs to the same distribution as cc from permuted data
pv = 2 * normcdf(-abs(zval),cc_mean,cc_std); 

%# plot
hist(cc_iter,20)
line([cc cc],ylim,'color','r') %# real value

enter image description here

In addition, if you compute correlation with [cc pv] = corr(x,y), you get p-value of how your correlation is different from no correlation. This p-value is calculated from assumption that your vector distributed normally. However, if you calculate not Pearson, but Spearman or Kendall correlation (non-parametric), those p-values will be from randomly permuted data:

[cc pv] = corr(x,y,'type','Spearman')
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I agree with kol: significance testing is, indeed, essential. Furthermore, I'd strongly advise you to plot the data (scatterplot) and really look at (visually inspect) it for a number of reasons:

1.) Outliers can exert 'leverage effect'. Here's an example of a bivariate normal distribution (no correlation) with one outlier, resulting in a 'false positive' correlation:

x = [6.132527 14.308708 12.762164 14.330498 12.279083  1.345756  9.685630 8.430774 19.750663 1.252169 100]'
y = [16.589414 11.178509 13.755179  6.097675 14.221655 12.629690  8.186024 19.758320 10.787788 15.235328 250]'

2.) Pearson's correlation was designed for linear relationships. For curvilinear ones Spearman's rho is better (the English wiki-article on the topic is very illustrative).

If I get you right, your supervisor suggests you to run a bootstrapping test. I cannot help you with a concrete solution but my experience (from neuroscience and/or experimental psychology, I have no idea what's going on in, say, engineering science :-)) is that bootstrapping is not very common in correlation significance testing.

I also fully agree with kol that the coefficient of determination is often regarded as 'common variance' or 'explained variance'. However, there are alternative approaches (an unorthodox one is the 'binomial effect size display' by Rosenthal & Rubin (1982)). I'd be careful in interpreting only r^2 > .5 as 'practically significant', although I agree with kol that statistical significance is not the same as effect size.

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