Implementing PCA/Whitening
From Ufldl
for
Implementing PCA/Whitening
Jump to:
navigation
,
search
In this section, we summarize the PCA, PCA whitening and ZCA whitening algorithms, and also describe how you can implement them using efficient linear algebra libraries. First, we need to ensure that the data has (approximately) zero-mean. For natural images, we achieve this (approximately) by subtracting the mean value of each image patch. We achieve this by computing the mean for each patch and subtracting it for each patch. In Matlab, we can do this by using avg = mean(x, 1); x = x - repmat(avg, size(x, 1), 1); Next, we need to compute <math>\textstyle \Sigma = \frac{1}{m} \sum_{i=1}^m (x^{(i)})(x^{(i)})^T</math>. If you're implementing this in Matlab (or even if you're implementing this in C++, Java, etc., but have access to an efficient linear algebra library), doing it as an explicit sum is inefficient. Instead, we can compute this in one fell swoop as sigma = x * x' / size(x, 2); (Check the math yourself for correctness.) Here, we assume that <math>x</math> is a data structure that contains one training example per column (so, <math>x</math> is a <math>\textstyle n</math>-by-<math>\textstyle m</math> matrix). Next, PCA computes the eigenvectors of <math>\Sigma</math>. One could do this using the Matlab <tt>eig</tt> function. However, because <math>\Sigma</math> is a symmetric positive semi-definite matrix, it is more numerically reliable to do this using the <tt>svd</tt> function. Concretely, if you implement [U,S,V] = svd(sigma); then the matrix <math>U</math> will contain the eigenvectors of <math>Sigma</math> (one eigenvector per column, sorted in order from top to bottom eigenvector), and the diagonal entries of the matrix <math>S</math> will contain the corresponding eigenvalues (also sorted in decreasing order). The matrix <math>V</math> will be equal to transpose of <math>U</math>, and can be safely ignored. (Note: The <tt>svd</tt> function actually computes the singular vectors and singular values of a matrix, which for the special case of a symmetric positive semi-definite matrix---which is all that we're concerned with here---is equal to its eigenvectors and eigenvalues. A full discussion of singular vectors vs. eigenvectors is beyond the scope of these notes.) Finally, you can compute <math>\textstyle x_{\rm rot}</math> and <math>\textstyle \tilde{x}</math> as follows: xRot = U' * x; % rotated version of the data. xTilde = U(:,1:k)' * x; % reduced dimension representation of the data, % where k is the number of eigenvectors to keep This gives your PCA representation of the data in terms of <math>\textstyle \tilde{x} \in \Re^k</math>. Incidentally, if <math>x</math> is a <math>\textstyle n</math>-by-<math>\textstyle m</math> matrix containing all your training data, this is a vectorized implementation, and the expressions above work too for computing <math>x_{\rm rot}</math> and <math>\tilde{x}</math> for your entire training set all in one go. The resulting <math>x_{\rm rot}</math> and <math>\tilde{x}</math> will have one column corresponding to each training example. To compute the PCA whitened data <math>\textstyle x_{\rm PCAwhite}</math>, use xPCAwhite = diag(1./sqrt(diag(S) + epsilon)) * U' * x; Since <math>S</math>'s diagonal contains the eigenvalues <math>\textstyle \lambda_i</math>, this turns out to be a compact way of computing <math>\textstyle x_{{\rm PCAwhite},i} = \frac{x_{{\rm rot},i} }{\sqrt{\lambda_i}}</math> simultaneously for all <math>\textstyle i</math>. Finally, you can also compute the ZCA whitened data <math>\textstyle x_{\rm ZCAwhite}</math> as: xZCAwhite = U * diag(1./sqrt(diag(S) + epsilon)) * U' * x;
Template:Languages
(
view source
)
Template:PCA
(
view source
)
Return to
Implementing PCA/Whitening
.
Views
Page
Discussion
View source
History
Personal tools
Log in
ufldl resources
UFLDL Tutorial
Recommended Readings
wiki
Main page
Recent changes
Random page
Help
Search
Toolbox
What links here
Related changes
Special pages