# Principal Component Analysis and determinant of the total scatter matrix

Hi guys I'm reading a paper Eigenfaces vs. Fisherfaces: Recognition Using Class Specific Linear Projection, I'm wondering why in PCA the projection W is chosen to maximize the determinant of the total scatter matrix of the projected samples, i.e., arg max|W^T S_T W|(in latex form) where S_T is the scatter matrix of the original dataset. Thanks very much!

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## 1 Answer

The expression makes sense if we note that the eigenvalues of a matrix can be found from the determinant using the characteristic equation.

### (Quick review of PCA)

You probably know already that since we are performing a principle component analysis (PCA) of `S_T`, our goal is to find a diagonal matrix B such that

``````B = W^(T) * S_T * W
``````

`W^(T)` is the transpose of W. The elements of the diagonal matrix B are the eigenvalues, and the column vectors of W are the eigenvectors. This gives us the Principal Components we seek.

### Back to the characteristic equation:

The Determinant of a matrix can be used to find its eigenvalues from the characteristic equation. Quoting straight from wikipedia:

(where I is the identity matrix). Since v is non-zero, this means that the matrix I − A is singular, which in turn means that its determinant is 0 (non-invertible). Thus the roots of the function `det( I − A)` are the eigenvalues of A...

http://en.wikipedia.org/wiki/Characteristic_polynomial

Thus by maximizing the determinant, or finding its roots, you are able to find the eigenvalues.

### Read more:

http://en.wikipedia.org/wiki/Determinant#Relation_to_eigenvalues_and_trace http://en.wikipedia.org/wiki/Eigenvalues_and_eigenvectors

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Hi Aman, thanks for your answer, but why our goal is to find a diagonal matrix B? Why it's diagonal, can you give me a reference? I learn PCA from Duda's Pattern Classification book, in that book, they want the distance between original data and projected data to be minimized. –  Lenny Apr 6 '12 at 5:18
@Lenny - Sorry for delayed response, I somehow missed your comment. Imagine we have a collection of objects, each of which is described by 10 observable properties. Each object can be considered as a single point in the 10-dimensional property-space; each property is an axis in this space. But some properties may be correlated, so these axes are not orthogonal. Through PCA (using diagonalization), we find a new coordinate system in which each "principle" axis is based on a combination of the original properties, avoiding correlation and expressing maximum variation in fewer dimensions. –  Aman Apr 18 '12 at 23:49
@Lenny - To learn more, check out (of course) wikipedia en.wikipedia.org/wiki/Principal_component_analysis .. also, I liked the introduction to PCA in Chapter 14 of the O'Reilly book "Data Analysis with Open Source Tools", but it has not a general discussion but a specific use of PCA. shop.oreilly.com/product/9780596802363.do –  Aman Apr 18 '12 at 23:58
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