Matlab - PCA analysis and reconstruction of multi dimensional data
I have a large dataset of multidimensional data(132 dimensions).
I am a beginner at performing data mining and I want to apply Principal Components Analysis by using Matlab. However, I have seen that there are a lot of functions explained on the web but I do not understand how should they be applied.
Basically, I want to apply PCA and to obtain the eigenvectors and their corresponding eigenvalues out of my data.
After this step I want to be able to do a reconstruction for my data based on a selection of the obtained eigenvectors.
I can do this manually, but I was wondering if there are any predefined functions which can do this because they should already be optimized.
My initial data is something like : size(x) = [33800 132]
. So basically I have 132
features(dimensions) and 33800
data points. And I want to perform PCA on this data set.
Any help or hint would do.
Here's a quick walkthrough. First we create a matrix of your hidden variables (or "factors"). It has 100 observations and there are two independent factors.
>> factors = randn(100, 2);
Now create a loadings matrix. This is going to map the hidden variables onto your observed variables. Say your observed variables have four features. Then your loadings matrix needs to be 4 x 2
>> loadings = [
1 0
0 1
1 1
1 -1 ];
That tells you that the first observed variable loads on the first factor, the second loads on the second factor, the third variable loads on the sum of factors and the fourth variable loads on the difference of the factors.
Now create your observations:
>> observations = factors * loadings' + 0.1 * randn(100,4);
I added a small amount of random noise to simulate experimental error. Now we perform the PCA using the pca
function from the stats toolbox:
>> [coeff, score, latent, tsquared, explained, mu] = pca(observations);
The variable score
is the array of principal component scores. These will be orthogonal by construction, which you can check -
>> corr(score)
ans =
1.0000 0.0000 0.0000 0.0000
0.0000 1.0000 0.0000 0.0000
0.0000 0.0000 1.0000 0.0000
0.0000 0.0000 0.0000 1.0000
The combination score * coeff'
will reproduce the centered version of your observations. The mean mu
is subtracted prior to performing PCA. To reproduce your original observations you need to add it back in,
>> reconstructed = score * coeff' + repmat(mu, 100, 1);
>> sum((observations - reconstructed).^2)
ans =
1.0e-27 *
0.0311 0.0104 0.0440 0.3378
To get an approximation to your original data, you can start dropping columns from the computed principal components. To get an idea of which columns to drop, we examine the explained
variable
>> explained
explained =
58.0639
41.6302
0.1693
0.1366
The entries tell you what percentage of the variance is explained by each of the principal components. We can clearly see that the first two components are more significant than the second two (they explain more than 99% of the variance between them). Using the first two components to reconstruct the observations gives the rank-2 approximation,
>> approximationRank2 = score(:,1:2) * coeff(:,1:2)' + repmat(mu, 100, 1);
We can now try plotting:
>> for k = 1:4
subplot(2, 2, k);
hold on;
grid on
plot(approximationRank2(:, k), observations(:, k), 'x');
plot([-4 4], [-4 4]);
xlim([-4 4]);
ylim([-4 4]);
title(sprintf('Variable %d', k));
end
We get an almost perfect reproduction of the original observations. If we wanted a coarser approximation, we could just use the first principal component:
>> approximationRank1 = score(:,1) * coeff(:,1)' + repmat(mu, 100, 1);
and plot it,
>> for k = 1:4
subplot(2, 2, k);
hold on;
grid on
plot(approximationRank1(:, k), observations(:, k), 'x');
plot([-4 4], [-4 4]);
xlim([-4 4]);
ylim([-4 4]);
title(sprintf('Variable %d', k));
end
This time the reconstruction isn't so good. That's because we deliberately constructed our data to have two factors, and we're only reconstructing it from one of them.
Note that despite the suggestive similarity between the way we constructed the original data and its reproduction,
>> observations = factors * loadings' + 0.1 * randn(100,4);
>> reconstructed = score * coeff' + repmat(mu, 100, 1);
there is not necessarily any correspondence between factors
and score
, or between loadings
and coeff
. The PCA algorithm doesn't know anything about the way your data is constructed - it merely tries to explain as much of the total variance as it can with each successive component.
User @Mari asked in the comments how she could plot the reconstruction error as a function of the number of principal components. Using the variable explained
above this is quite easy. I'll generate some data with a more interesting factor structure to illustrate the effect -
>> factors = randn(100, 20);
>> loadings = chol(corr(factors * triu(ones(20))))';
>> observations = factors * loadings' + 0.1 * randn(100, 20);
Now all of the observations load on a significant common factor, with other factors of decreasing importance. We can get the PCA decomposition as before
>> [coeff, score, latent, tsquared, explained, mu] = pca(observations);
and plot the percentage of explained variance as follows,
>> cumexplained = cumsum(explained);
cumunexplained = 100 - cumexplained;
plot(1:20, cumunexplained, 'x-');
grid on;
xlabel('Number of factors');
ylabel('Unexplained variance')
You have a pretty good dimensionality reduction toolbox at http://homepage.tudelft.nl/19j49/Matlab_Toolbox_for_Dimensionality_Reduction.html Besides PCA, this toolbox has a lot of other algorithms for dimensionality reduction.
Example of doing PCA:
Reduced = compute_mapping(Features, 'PCA', NumberOfDimension);