41

I am a little bit confused about the data augmentation performed in PyTorch. Now, as far as I know, when we are performing data augmentation, we are KEEPING our original dataset, and then adding other versions of it (Flipping, Cropping...etc). But that doesn't seem like happening in PyTorch. As far as I understood from the references, when we use data.transforms in PyTorch, then it applies them one by one. So for example:

data_transforms = {
    'train': transforms.Compose([
        transforms.RandomResizedCrop(224),
        transforms.RandomHorizontalFlip(),
        transforms.ToTensor(),
        transforms.Normalize([0.485, 0.456, 0.406], [0.229, 0.224, 0.225])
    ]),
    'val': transforms.Compose([
        transforms.Resize(256),
        transforms.CenterCrop(224),
        transforms.ToTensor(),
        transforms.Normalize([0.485, 0.456, 0.406], [0.229, 0.224, 0.225])
    ]),
}

Here , for the training, we are first randomly cropping the image and resizing it to shape (224,224). Then we are taking these (224,224) images and horizontally flipping them. Therefore, our dataset is now containing ONLY the horizontally flipped images, so our original images are lost in this case.

Am I right? Is this understanding correct? If not, then where do we tell PyTorch in this code above (taken from Official Documentation) to keep the original images and resize them to the expected shape (224,224)?

Thanks

27

The transforms operations are applied to your original images at every batch generation. So your dataset is left unchanged, only the batch images are copied and transformed every iteration.

The confusion may come from the fact that often, like in your example, transforms are used both for data preparation (resizing/cropping to expected dimensions, normalizing values, etc.) and for data augmentation (randomizing the resizing/cropping, randomly flipping the images, etc.).


What your data_transforms['train'] does is:

  • Randomly resize the provided image and randomly crop it to obtain a (224, 224) patch
  • Apply or not a random horizontal flip to this patch, with a 50/50 chance
  • Convert it to a Tensor
  • Normalize the resulting Tensor, given the mean and deviation values you provided

What your data_transforms['val'] does is:

  • Resize your image to (256, 256)
  • Center crop the resized image to obtain a (224, 224) patch
  • Convert it to a Tensor
  • Normalize the resulting Tensor, given the mean and deviation values you provided

(i.e. the random resizing/cropping for the training data is replaced by a fixed operation for the validation one, to have reliable validation results)


If you don't want your training images to be horizontally flipped with a 50/50 chance, just remove the transforms.RandomHorizontalFlip() line.

Similarly, if you want your images to always be center-cropped, replace transforms.RandomResizedCrop by transforms.Resize and transforms.CenterCrop, as done for data_transforms['val'].

| improve this answer | |
  • Thanks for you answer. So meaning that the CNN will not be trained on the original images I have, only the horizontally flipped images. Right? – H.S Aug 3 '18 at 18:25
  • Not exactly right. Your network will be trained on patches of images which are randomly resized and cropped from the original dataset, and which are sometimes horizontally flipped (probability = 0.5). – benjaminplanche Aug 3 '18 at 18:49
  • 4
    It's still unclear to me which transformations increase the size of the dataset and which transformations will change the original image? – insanely_sin Feb 15 '19 at 1:38
  • 4
    @insanely_sin: All transformations somehow change the image (they leave the original untouched, just returning a changed copy). Given the same input image, some methods will always apply the same changes (e.g., converting it to Tensor, resizing to a fixed shape, etc.). Other methods will apply transformations with random parameters, returning different results each time (e.g., randomly cropping the images, randomly changing their brightness or saturation, etc.). Because the latter transformations return different images each time (from the same original samples), they augment the dataset. – benjaminplanche Feb 15 '19 at 11:34
45

I assume you are asking whether these data augmentation transforms (e.g. RandomHorizontalFlip) actually increase the size of the dataset as well, or are they applied on each item in the dataset one by one and not adding to the size of the dataset.

Running the following simple code snippet we could observe that the latter is true, i.e. if you have a dataset of 8 images, and create a PyTorch dataset object for this dataset when you iterate through the dataset, the transformations are called on each data point, and the transformed data point is returned. So for example if you have random flipping, some of the data points are returned as original, some are returned as flipped (e.g. 4 flipped and 4 original). In other words, by one iteration through the dataset items, you get 8 data points(some flipped and some not). [Which is at odds with the conventional understanding of augmenting the dataset(e.g. in this case having 16 data points in the augmented dataset)]

class experimental_dataset(Dataset):

    def __init__(self, data, transform):
        self.data = data
        self.transform = transform

    def __len__(self):
        return len(self.data.shape[0])

    def __getitem__(self, idx):
        item = self.data[idx]
        item = self.transform(item)
        return item

    transform = transforms.Compose([
        transforms.ToPILImage(),
        transforms.RandomHorizontalFlip(),
        transforms.ToTensor()
    ])

x = torch.rand(8, 1, 2, 2)
print(x)

dataset = experimental_dataset(x,transform)

for item in dataset:
    print(item)

Results: (The little differences in floating points are caused by transforming to pil image and back)

Original dummy dataset:

tensor([[[[0.1872, 0.5518],
          [0.5733, 0.6593]]],


    [[[0.6570, 0.6487],
      [0.4415, 0.5883]]],


    [[[0.5682, 0.3294],
      [0.9346, 0.1243]]],


    [[[0.1829, 0.5607],
      [0.3661, 0.6277]]],


    [[[0.1201, 0.1574],
      [0.4224, 0.6146]]],


    [[[0.9301, 0.3369],
      [0.9210, 0.9616]]],


    [[[0.8567, 0.2297],
      [0.1789, 0.8954]]],


    [[[0.0068, 0.8932],
      [0.9971, 0.3548]]]])

transformed dataset:

tensor([[[0.1843, 0.5490],
     [0.5725, 0.6588]]])
tensor([[[0.6549, 0.6471],
     [0.4392, 0.5882]]])
tensor([[[0.5647, 0.3255],
         [0.9333, 0.1216]]])
tensor([[[0.5569, 0.1804],
         [0.6275, 0.3647]]])
tensor([[[0.1569, 0.1176],
         [0.6118, 0.4196]]])
tensor([[[0.9294, 0.3333],
         [0.9176, 0.9608]]])
tensor([[[0.8549, 0.2275],
         [0.1765, 0.8941]]])
tensor([[[0.8902, 0.0039],
         [0.3529, 0.9961]]])
| improve this answer | |
  • 6
    I think this is the answer to the question the OP really asked. – Nicole Finnie Apr 21 '19 at 22:16
  • 5
    So that means that upon every epoch you get a different version of the dataset, right? – Alexandros Aug 21 '19 at 15:31
  • 2
    @Alexandros Yes – Ashkan372 Aug 29 '19 at 14:08
  • 3
    @pooria Not necessarily. The purpose of data augmentation is trying to get an upper bound of the data distribution of unseen (test) data in a hope that the neural nets will be approximated to that data distribution with a trade-off that it approximates the original distribution of the train data (the test data is unlikely to be similar in reality). There's no one size fits all data augmentation approach or definition. – Nicole Finnie May 2 at 23:05
  • 1
    @pooria, you don't need to do at (explained by @NicoleFinnie)... however, if you have to do it like that for some reason, you can generate a new dataset by using the transformation available in pytorch, save it.. and train on the new one.. (though I would not recommend it, do it only if you have a specific reason for it) – Ashkan372 Jun 2 at 10:04

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