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I am working on a Kaggle dataset: https://www.kaggle.com/c/santander-customer-satisfaction. I understand some sort of feature scaling is needed before PCA. I read from this post and this post that normalization is best, however it was standardizing that gave me the highest performance (AUC-ROC).

I tried all the feature scaling methods from sklearn, including: RobustScaler(), Normalizer(), MinMaxScaler(), MaxAbsScaler() and StandardScaler(). Then using the scaled data, I did PCA. But it turns out that the optimal numbers of PCA's obtained vary greatly between these methods.

Here's the code I use:

# Standardize the data
scaler = StandardScaler()
X_train_scaled = scaler.fit_transform(X_train)

# Find the optimal number of PCA 
pca = PCA(n_components=X_train_scaled.shape[1])
pca.fit(X_train_scaled)
ratios = pca.explained_variance_ratio_

# Plot the explained variance ratios
x = np.arange(X_train_scaled.shape[1])
plt.plot(x, np.cumsum(ratios), '-o')
plt.xlabel("Number of PCA's")
plt.ylabel("Cumulated Sum of Explained Variance")
plt.title("Variance Explained by PCA's")

# Find the optimal number of PCA's
for i in range(np.cumsum(ratios).shape[0]):
  if np.cumsum(ratios)[i] >= 0.99:
    num_pca = i + 1
    print "The optimal number of PCA's is: {}".format(num_pca)
    break
  else:
    continue

These are the different number of PCA's I got using different scalers.

  • RobustScaler: 9
  • Normalizer: 26
  • MinMaxScaler: 45
  • MaxAbsScaler: 45
  • StandardScaler: 142

So, my question is, which method is the right one for feature scaling in this situation? Thanks!

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    This is just a comment - 142 principal components sort of defeats the purpose of dimension reduction, which is one of the core use cases of principal component analysis. I'm also unsure explaining >99% variance through PCA is optimal,or something that people usually attempt to do. May be worth revisiting your process/asking around to make sure it's statistically sound. – Info5ek Feb 23 '19 at 5:25
16

Data on which the PCA-transformation is calculated should be normalized, meaning in this case:

  • zero mean
  • unit variance

This basically is sklearns StandardScaler, which i would prefer of your candidates. The reasons are explained on Wiki and also here.

  • sklearns Normalizer is missing zero-mean
  • Both Min-Max scalers are missing unit-variance
  • Robust scaler could work on some data (outliers!), but i would prefer StandardScaler.
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  • 1
    Got it. Thank you @sascha! – George Liu May 14 '16 at 2:07
3

You need to normalize the features or their variances will not be comparable. Think of a feature where the variance is a ratio to the range. A larger range produces a larger variance. You don't want the PCA to focus on variables with larger ranges.

R code illustrating change in var due to range

> v=runif(100)
> x=v/4 # change only the range
> var(x)
[1] 0.004894443
> var(v)
[1] 0.07831109
> var(x/sum(x))
[1] 3.169311e-05
> var(v/sum(v))
[1] 3.169311e-05

After normalizing, we see the same variance with x and v.

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