Yes, you are nearly right. The `pca.explained_variance_ratio_`

parameter returns a vector of the variance explained by each dimension. Thus `pca.explained_variance_ratio_[i]`

gives the variance explained solely by the i+1st dimension.

You probably want to do `pca.explained_variance_ratio_.cumsum()`

. That will return a vector `x`

such that `x[i]`

returns the *cumulative* variance explained by the first i+1 dimensions.

```
import numpy as np
from sklearn.decomposition import PCA
np.random.seed(0)
my_matrix = np.random.randn(20, 5)
my_model = PCA(n_components=5)
my_model.fit_transform(my_matrix)
print my_model.explained_variance_
print my_model.explained_variance_ratio_
print my_model.explained_variance_ratio_.cumsum()
```

```
[ 1.50756565 1.29374452 0.97042041 0.61712667 0.31529082]
[ 0.32047581 0.27502207 0.20629036 0.13118776 0.067024 ]
[ 0.32047581 0.59549787 0.80178824 0.932976 1. ]
```

So in my random toy data, if I picked `k=4`

I would retain 93.3% of the variance.