As you well guessed the fitting is done properly, although I would suggest increasing the `chunk_size`

to 100 or 1000 (or even higher, depending on the shape of your data).

What you have to do now to transform it, is actually transforming it:

```
out = my_new_features_dataset # shape N x 2
for i in range(0, num_rows//chunk_size):
out[i*chunk_size:(i+1) * chunk_size] = ipca.transform(features[i*chunk_size : (i+1)*chunk_size])
```

And thats should give you your new transformed features. If you still have too many samples to fit in memory, I would suggest using `out`

as another hdf5 dataset.

Also, I would argue that reducing a huge dataset to 2 components is probably not a very good idea. But is hard to say without knowing the shape of your `features`

. I would suggest reducing them to `sqrt(features.shape[1])`

, as it is a decent heuristic, or pro tip: use `ipca.explained_variance_ratio_`

to determine the best amount of features for your affordable information loss threshold.

Edit: as for the `explained_variance_ratio_`

, it returns a vector of dimension `n_components`

(the `n_components`

that you pass as parameter to IPCA) where each value *i* inicates the percentage of the variance of your original data explained by the *i*-th new component.

You can follow the procedure in this answer to extract how much information is preserved by the first *n* components:

```
>>> print(ipca.explained_variance_ratio_.cumsum())
[ 0.32047581 0.59549787 0.80178824 0.932976 1. ]
```

Note: numbers are ficticius taken from the answer above assuming that you have reduced IPCA to 5 components. The *i*-th number indicates how much of the original data is explained by the first [0, i] components, as it is the cummulative sum of the explained variance ratio.

Thus, what is usually done, is to fit your PCA to the same number of components than your original data:

```
ipca = IncrementalPCA(n_components=features.shape[1])
```

Then, after training on your whole data (with iteration + `partial_fit`

) you can plot `explaine_variance_ratio_.cumsum()`

and choose how much data you want to lose. Or do it automatically:

```
k = np.argmax(ipca.explained_variance_ratio_.cumsum() > 0.9)
```

The above will return the first index on the cumcum array where the value is `> 0.9`

, this is, indicating the number of PCA components that preserve at least 90% of the original data.

Then you can tweek the transformation to reflect it:

```
cs = chunk_size
out = my_new_features_dataset # shape N x k
for i in range(0, num_rows//chunk_size):
out[i*cs:(i+1)*cs] = ipca.transform(features[i*cs:(i+1)*cs])[:, :k]
```

NOTE the slicing to `:k`

to just select only the first `k`

components while ignoring the rest.