I can perform PCA in scikit by code below: X_train has 279180 rows and 104 columns.

from sklearn.decomposition import PCA
pca = PCA(n_components=30)
X_train_pca = pca.fit_transform(X_train)

Now, when I want to project the eigenvectors onto feature space, I must do following:

""" Projection """
comp = pca.components_ #30x104
com_tr = np.transpose(pca.components_) #104x30
proj = np.dot(X_train,com_tr) #279180x104 * 104x30 = 297180x30

But I am hesitating with this step, because Scikit documentation says:

components_: array, [n_components, n_features]

Principal axes in feature space, representing the directions of maximum variance in the data.

It seems to me, that it is already projected, but when I checked the source code, it returns only the eigenvectors.

What is the right way how to project it?

Ultimately, I am aiming to calculate the MSE of reconstruction.

""" Reconstruct """
recon = np.dot(proj,comp) #297180x30 * 30x104 = 279180x104

"""  MSE Error """
print "MSE = %.6G" %(np.mean((X_train - recon)**2))

You can do

proj = pca.inverse_transform(X_train_pca)

That way you do not have to worry about how to do the multiplications.

What you obtain after pca.fit_transform or pca.transform are what is usually called the "loadings" for each sample, meaning how much of each component you need to describe it best using a linear combination of the components_ (the principal axes in feature space).

The projection you are aiming at is back in the original signal space. This means that you need to go back into signal space using the components and the loadings.

So there are three steps to disambiguate here. Here you have, step by step, what you can do using the PCA object and how it is actually calculated:

  1. pca.fit estimates the components (using an SVD on the centered Xtrain):

    from sklearn.decomposition import PCA
    import numpy as np
    from numpy.testing import assert_array_almost_equal
    #Should this variable be X_train instead of Xtrain?
    X_train = np.random.randn(100, 50)
    pca = PCA(n_components=30)
    U, S, VT = np.linalg.svd(X_train - X_train.mean(0))
    assert_array_almost_equal(VT[:30], pca.components_)
  2. pca.transform calculates the loadings as you describe

    X_train_pca = pca.transform(X_train)
    X_train_pca2 = (X_train - pca.mean_).dot(pca.components_.T)
    assert_array_almost_equal(X_train_pca, X_train_pca2)
  3. pca.inverse_transform obtains the projection onto components in signal space you are interested in

    X_projected = pca.inverse_transform(X_train_pca)
    X_projected2 = X_train_pca.dot(pca.components_) + pca.mean_
    assert_array_almost_equal(X_projected, X_projected2)

You can now evaluate the projection loss

loss = ((X_train - X_projected) ** 2).mean()
  • Ok, so I can call pca.fit to calculate the components, then the projection can be calculated by pca.fit_transform (that is also when I want to work further with the data - fetch them to some model since the dimensionality is reducted). And for reconstruction, I call pca.invert_transform to calculate MSE. Is that correct? – HonzaB Apr 12 '16 at 9:00
  • 1
    It depends on what you mean by projection. First, note that pca.fit_transform(X) gives the same result as pca.fit(X).transform(X) (it is an optimized shortcut). Second, a projection is generally something that goes from one space into the same space, so here it would be from signal space to signal space, with the property that applying it twice is like applying it once. Here it would be f= lambda X: pca.inverse_transform(pca.transform(X)). You can check that f(f(X)) == f(X). So I would call that the projection. pca.transform is obtaining the loadings. In the end it's just terminolgy – eickenberg Apr 12 '16 at 9:06
  • 1
    super awesome explanatory answer – StephenBoesch Feb 16 '18 at 20:48
  • 2
    Just wanted to say that assert_array_almost_equal(VT[:30], pca.components_) is not always true. In the implementation of PCA the signs are shuffled around between U and V. To mimic this shuffling replace U, S, VT = np.linalg.svd(Xtrain - Xtrain.mean(0)) by U, S, VT = np.linalg.svd(Xtrain - Xtrain.mean(0), full_matrices=False) and insert from sklearn.utils.extmath import svd_flip followed by U, VT = svd_flip(U, VT). – Stan Jan 31 '19 at 16:19
  • 1
    Does X_train in loss = ((X_train - X_projected) ** 2).mean() replace Xtrain variable defined earlier in the code? – Josmoor98 Feb 28 '19 at 17:50

Adding on @eickenberg's post, here is how to do the pca reconstruction of digits' images:

import numpy as np
import matplotlib.pyplot as plt
from sklearn.datasets import load_digits
from sklearn import decomposition

n_components = 10
image_shape = (8, 8)

digits = load_digits()
digits = digits.data

n_samples, n_features = digits.shape
estimator = decomposition.PCA(n_components=n_components, svd_solver='randomized', whiten=True)
digits_recons = estimator.inverse_transform(estimator.fit_transform(digits))

# show 5 randomly chosen digits and their PCA reconstructions with 10 dominant eigenvectors
indices = np.random.choice(n_samples, 5, replace=False)
for i in range(len(indices)):
    plt.subplot(1,5,i+1), plt.imshow(np.reshape(digits[indices[i],:], image_shape)), plt.axis('off')
plt.suptitle('Original', size=25)
for i in range(len(indices)):
    plt.subplot(1,5,i+1), plt.imshow(np.reshape(digits_recons[indices[i],:], image_shape)), plt.axis('off')
plt.suptitle('PCA reconstructed'.format(n_components), size=25)

enter image description here

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