First of all, I assume that you call `features`

the variables and `not the samples/observations`

. In this case, you could do something like the following by creating a `biplot`

function that shows everything in one plot. In this example, I am using the iris data.

Before the example, please note that the **basic idea when using PCA as a tool for feature selection is to select variables according to the magnitude (from largest to smallest in absolute values) of their coefficients (loadings)**. See my last paragraph after the plot for more details.

**Overview:**

**PART1**: I explain how to check the importance of the features and how to plot a biplot.

**PART2**: I explain how to check the importance of the features and how to save them into a pandas dataframe using the feature names.

## PART 1:

```
import numpy as np
import matplotlib.pyplot as plt
from sklearn import datasets
from sklearn.decomposition import PCA
import pandas as pd
from sklearn.preprocessing import StandardScaler
iris = datasets.load_iris()
X = iris.data
y = iris.target
#In general a good idea is to scale the data
scaler = StandardScaler()
scaler.fit(X)
X=scaler.transform(X)
pca = PCA()
x_new = pca.fit_transform(X)
def myplot(score,coeff,labels=None):
xs = score[:,0]
ys = score[:,1]
n = coeff.shape[0]
scalex = 1.0/(xs.max() - xs.min())
scaley = 1.0/(ys.max() - ys.min())
plt.scatter(xs * scalex,ys * scaley, c = y)
for i in range(n):
plt.arrow(0, 0, coeff[i,0], coeff[i,1],color = 'r',alpha = 0.5)
if labels is None:
plt.text(coeff[i,0]* 1.15, coeff[i,1] * 1.15, "Var"+str(i+1), color = 'g', ha = 'center', va = 'center')
else:
plt.text(coeff[i,0]* 1.15, coeff[i,1] * 1.15, labels[i], color = 'g', ha = 'center', va = 'center')
plt.xlim(-1,1)
plt.ylim(-1,1)
plt.xlabel("PC{}".format(1))
plt.ylabel("PC{}".format(2))
plt.grid()
#Call the function. Use only the 2 PCs.
myplot(x_new[:,0:2],np.transpose(pca.components_[0:2, :]))
plt.show()
```

**Visualize what's going on using the biplot**

**Now, the importance of each feature is reflected by the magnitude of the corresponding values in the eigenvectors (higher magnitude - higher importance)**

Let's see first what amount of variance does each PC explain.

```
pca.explained_variance_ratio_
[0.72770452, 0.23030523, 0.03683832, 0.00515193]
```

`PC1 explains 72%`

and `PC2 23%`

. Together, if we keep PC1 and PC2 only, they explain `95%`

.

Now, let's find the most important features.

```
print(abs( pca.components_ ))
[[0.52237162 0.26335492 0.58125401 0.56561105]
[0.37231836 0.92555649 0.02109478 0.06541577]
[0.72101681 0.24203288 0.14089226 0.6338014 ]
[0.26199559 0.12413481 0.80115427 0.52354627]]
```

**Here, **`pca.components_`

has shape `[n_components, n_features]`

. Thus, by looking at the `PC1`

(First Principal Component) which is the first row: `[0.52237162 0.26335492 0.58125401 0.56561105]]`

we can conclude that `feature 1, 3 and 4`

(or Var 1, 3 and 4 in the biplot) are the most important. This is also clearly visible from the biplot (that's why we often use this plot to summarize the information in a visual way).

To sum up, look at the absolute values of the Eigenvectors' components corresponding to the k largest Eigenvalues. In `sklearn`

the components are sorted by `explained_variance_`

. The larger they are these absolute values, the more a specific feature contributes to that principal component.

## PART 2:

**The important features are the ones that influence more the components and thus, have a large absolute value/score on the component.**

To **get the most important features on the PCs** with names and save them into a **pandas dataframe** use this:

```
from sklearn.decomposition import PCA
import pandas as pd
import numpy as np
np.random.seed(0)
# 10 samples with 5 features
train_features = np.random.rand(10,5)
model = PCA(n_components=2).fit(train_features)
X_pc = model.transform(train_features)
# number of components
n_pcs= model.components_.shape[0]
# get the index of the most important feature on EACH component
# LIST COMPREHENSION HERE
most_important = [np.abs(model.components_[i]).argmax() for i in range(n_pcs)]
initial_feature_names = ['a','b','c','d','e']
# get the names
most_important_names = [initial_feature_names[most_important[i]] for i in range(n_pcs)]
# LIST COMPREHENSION HERE AGAIN
dic = {'PC{}'.format(i): most_important_names[i] for i in range(n_pcs)}
# build the dataframe
df = pd.DataFrame(dic.items())
```

**This prints:**

```
0 1
0 PC0 e
1 PC1 d
```

**So on the PC1 the feature named **`e`

is the most important and on PC2 the `d`

.

Nice article as well here: https://towardsdatascience.com/pca-clearly-explained-how-when-why-to-use-it-and-feature-importance-a-guide-in-python-7c274582c37e?source=friends_link&sk=65bf5440e444c24aff192fedf9f8b64f