I figured it out. I created a custom class which inherits from tensorflow.keras.utils.Sequence that performs the augmentations using scipy for each image.

```
class CustomDataset(tf.keras.utils.Sequence):
def __init__(self, batch_size, *args, **kwargs):
self.batch_size = batch_size
self.X_train = args[0]
self.Y_train = args[1]
def __len__(self):
# returns the number of batches
return int(self.X_train.shape[0] / self.batch_size)
def __getitem__(self, index):
# returns one batch
X = []
y = []
for i in range(self.batch_size):
r = random.randint(0, self.X_train.shape[0] - 1)
next_x = self.X_train[r]
next_y = self.Y_train[r]
augmented_next_x = []
###
### Augmentation parameters for this clip.
###
rotation_amt = random.randint(-45, 45)
for j in range(self.X_train.shape[1]):
transformed_img = ndimage.rotate(next_x[j], rotation_amt, reshape=False)
transformed_img[transformed_img == 0] = 255
augmented_next_x.append(transformed_img)
X.append(augmented_next_x)
y.append(next_y)
X = np.array(X).astype('uint8')
y = np.array(y)
encoder = LabelBinarizer()
y = encoder.fit_transform(y)
return X, y
def on_epoch_end(self):
# option method to run some logic at the end of each epoch: e.g. reshuffling
pass
```

I then pass this in to the `fit_generator`

method:

```
training_data_augmentation = CustomDataset(BS, X_train_L, y_train_L)
model.fit_generator(
training_data_augmentation,
epochs=300)
```