deflation Method for Penalized Matrix Decomposition Sparse PCA

The printable version is no longer supported and may have rendering errors. Please update your browser bookmarks and please use the default browser print function instead.

In the penalized matrix decomposition proposed by Witten, Tibshirani and Hastie<ref name="WTH2009">Daniela M. Witten, Robert Tibshirani, and Trevor Hastie. (2009) "A penalized matrix decomposition, with applications to sparse principal components and canonical correlation analysis". Biostatistics, 10(3):515–534.</ref>, after the penalized vectors [math]\displaystyle{ \,\textbf{v}_k }[/math] and [math]\displaystyle{ \,\textbf{u}_k }[/math] and the constant [math]\displaystyle{ \,d_k }[/math] have been determined, the data matrix [math]\displaystyle{ \,\textbf{X}^k }[/math] is deflated using the following formula:

[math]\displaystyle{ \textbf{X}^{k+1} = \textbf{X}^k - d_k\textbf{u}_k\textbf{v}_k^T }[/math]

The penalized matrix decomposition can be used to obtain a version of sparse PCA. In this case,

[math]\displaystyle{ \,\textbf{u}_k = \frac{\textbf{X}^k\textbf{v}_k}{\|\textbf{X}^k\textbf{v}_k\|_2} }[/math]

and

[math]\displaystyle{ \,\textbf{d}_k = \textbf{u}^T_k\textbf{X}^k\textbf{v}_k = \frac{\textbf{v}^T_k\textbf{X}^{kT}\textbf{X}^k\textbf{v}_k}{\|\textbf{X}^k\textbf{v}_k\|_2} = \frac{{\|\textbf{X}^k\textbf{v}_k\|^2_2}}{\|\textbf{X}^k\textbf{v}_k\|_2} = {\|\textbf{X}^k\textbf{v}_k\|_2}. }[/math]

Then,

[math]\displaystyle{ \textbf{X}^{k+1} = \textbf{X}^k - {\|\textbf{X}^k\textbf{v}_k\|_2}\frac{\textbf{X}^k\textbf{v}_k\textbf{v}_k^T}{\|\textbf{X}^k\textbf{v}_k\|_2} = \textbf{X}^k - \textbf{X}^k\textbf{v}_k\textbf{v}_k^T = \textbf{X}^k(I - \textbf{v}_k\textbf{v}_k^T). }[/math]

So if [math]\displaystyle{ \| \textbf{v}_k \|_2 = 1 }[/math] then the deflation method begin used for the penalized sparse PCA is the projection deflation method.

References

deflation Method for Penalized Matrix Decomposition Sparse PCA

References

Navigation menu

Search