# Python: Implement a PCA using SVD

I am trying to figure out the differences between PCA using Singular Value Decomposition as oppossed to PCA using Eigenvector-Decomposition.

Picture the following matrix:

`````` B = np.array([          [1, 2],
[3, 4],
[5, 6] ])
``````

When computing the PCA of this matrix B using eigenvector-Decomposition, we follow these steps:

1. Center the data (entries of B) by substracting the column-mean from each column
2. Compute the covariance matrix `C = Cov(B) = B^T * B / (m -1)`, where m = # rows of B
3. Find eigenvectors of C
4. `PCs = X * eigen_vecs`

When computing the PCA of matrix B using SVD, we follow these steps:

1. Compute SVD of B: `B = U * Sigma * V.T`
2. `PCs = U * Sigma`

I have done both for the given matrix.

With eigenvector-Decomposition I obtain this result:

``````[[-2.82842712  0.        ]
[ 0.          0.        ]
[ 2.82842712  0.        ]]
``````

With SVD I obtain this result:

``````[[-2.18941839  0.45436451]
[-4.99846626  0.12383458]
[-7.80751414 -0.20669536]]
``````

The result obtained with eigenvector-Decomposition is the result given as solution. So, why is the result obtained with the SVD different?

I know that: `C = Cov(B) = V * (Sigma^2)/(m-1)) * V.T` and I have a feeling this might be related to why the two results are different. Still. Can anyone help me understand better?

Please see below a comparision for your matrix with sklearn.decomposition.PCA and numpy.linalg.svd. Can you compare or post how you derived SVD results.

Code for sklearn.decomposition.PCA:

``````from sklearn.decomposition import PCA
import numpy as np
np.set_printoptions(precision=3)

B = np.array([[1.0,2], [3,4], [5,6]])

B1 = B.copy()
B1 -= np.mean(B1, axis=0)
n_samples = B1.shape
print("B1 is B after centering:")
print(B1)

cov_mat = np.cov(B1.T)
pca = PCA(n_components=2)
X = pca.fit_transform(B1)
print("X")
print(X)

eigenvecmat =   []
print("Eigenvectors:")
for eigenvector in pca.components_:
if eigenvecmat == []:
eigenvecmat = eigenvector
else:
eigenvecmat = np.vstack((eigenvecmat, eigenvector))
print(eigenvector)
print("eigenvector-matrix")
print(eigenvecmat)

print("CHECK FOR PCA:")
print("X * eigenvector-matrix (=B1)")
print(np.dot(PCs, eigenvecmat))
``````

Output for PCA:

``````B1 is B after centering:
[[-2. -2.]
[ 0.  0.]
[ 2.  2.]]
X
[[-2.828  0.   ]
[ 0.     0.   ]
[ 2.828  0.   ]]
Eigenvectors:
[0.707 0.707]
[-0.707  0.707]
eigenvector-matrix
[[ 0.707  0.707]
[-0.707  0.707]]
CHECK FOR PCA:
X * eigenvector-matrix (=B1)
[[-2. -2.]
[ 0.  0.]
[ 2.  2.]]
``````

numpy.linalg.svd:

``````print("B1 is B after centering:")
print(B1)

from numpy.linalg import svd
U, S, Vt = svd(X1, full_matrices=True)

print("U:")
print(U)
print("S used for building Sigma:")
print(S)
Sigma = np.zeros((3, 2), dtype=float)
Sigma[:2, :2] = np.diag(S)
print("Sigma:")
print(Sigma)
print(Vt)
print("CHECK FOR SVD:")
print("U * Sigma * Vt (=B1)")
print(np.dot(U, np.dot(Sigma, Vt)))
``````

Output for SVD:

``````B1 is B after centering:
[[-2. -2.]
[ 0.  0.]
[ 2.  2.]]
U:
[[-0.707  0.     0.707]
[ 0.     1.     0.   ]
[ 0.707  0.     0.707]]
S used for building Sigma:
[4. 0.]
Sigma:
[[4. 0.]
[0. 0.]
[0. 0.]]