Programmer Guide/Command Reference/EVAL/svd: Difference between revisions

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:;<var>V</var>:contains on return the MxM matrix ''V''
:;<var>V</var>:contains on return the MxM matrix ''V''
;Result 4: Computes the SVD of the transformed and squared input matrix ''T''.  
;Result 4: Computes the SVD of the transformed and squared input matrix ''T''.  
::<code>''C'' = trn(''T'') * ''T''
::<code>''C'' = trn(''T'') * ''T''</code>
::<code>solve: ''C'' = ''V'' * &Sigma; * trn(''V'')</code>
::<code>solve: ''C'' = ''V'' * &Sigma; * trn(''V'')</code>
:The results are stored in the (optional) numerical tables (references) ''S'' (Mx1, diagonal of &Sigma;) and ''V'' (MxM). The return value is the NxM matrix <code>''PC''=''A'' * ''V''</code>.
:The results are stored in the (optional) numerical tables (references) ''S'' (Mx1, diagonal of &Sigma;) and ''V'' (MxM). The return value is the NxM matrix <code>''PC''=''A'' * ''V''</code>.

Revision as of 09:49, 21 April 2011

Singular value decomposition (SVD).


Usage 1
svd(0, A, trn)
A
the NxM matrix to be transformed
trn
transformation to be applied to A
trn transformed matrix T (NxM) description trn(T)*T
(MxM)
0 T[i,j] = A[i,j] no transformation "Streumatrix"
1 T[i,j] = A[i,j]-avr(A) subtract matrix mean
2 T[i,j] = A[i,j]-avr(A[*,j]) subtract column mean (center columns) covariance matrix
3 T[i,j] = (A[i,j]-avr(A[*,j]))/dev(A[*,j]) subtract column mean, devide by column deviation (center and standardize columns) correlation matrix
4 T[i,j] = A[i,j]-(avr(A[i,*])+avr(A[*,j]))+avr(A) subtract row and column mean, add matrix mean (center rows and columns)
Result 1
The transformed matrix T.

Usage 2
svd(1, A, trn)
Result 2
Returns the matrix C=trn(T)*T. C is a square matrix with M rows and columns (MxM).

Usage 3
svd(2, A, trn, U, S, V)
U
contains on return the NxM matrix U
S
contains on return the vector S with M elements; Note: the returned vector contains the diagonal elements of the matrix Σ, which are called the singular values.
V
contains on return the MxM matrix V
Result 3
Computes the SVD of the transformed input matrix T.
solve: T = U * Σ * trn(V)
The results are stored in the (optional) numerical tables (references) U (NxM), S (Mx1, diagonal of Σ) and V (MxM). The return value is the NxM matrix PC=U * Σ.

Usage 4
svd(3, A, trn, U, S, V)
S
contains on return the vector S with M elements; Note: the returned vector contains the diagonal elements of the matrix Σ (singular values).
V
contains on return the MxM matrix V
Result 4
Computes the SVD of the transformed and squared input matrix T.
C = trn(T) * T
solve: C = V * Σ * trn(V)
The results are stored in the (optional) numerical tables (references) S (Mx1, diagonal of Σ) and V (MxM). The return value is the NxM matrix PC=A * V.

Usage 5
svd(4, C, S, V)
C
the MxM input data matrix
S
contains on return the vector S with M elements; Note: the returned vector contains the diagonal elements of the matrix Σ (singular values).
V
contains on return the MxM matrix V
Result 5
Computes the SVD of the matrix C. It is assumed that C is (optional) transformed and squared matrix derived from a NxM data matrix.
solve: C = V * Σ * trn(V)
The results are stored in the (optional) numerical tables (references) S (Mx1, diagonal of Σ) and V (MxM). The return value is always 0.

See also
var, corr, dist, haclust, modclust

<function list>

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