Left: input images / Right: output images with 4x super-resolution after 6 epochs:
See more examples inside the images folder.
In CVPR 2016 Shi et. al. from Twitter VX (previously Magic Pony) published a paper called Real-Time Single Image and Video Super-Resolution Using an Efficient Sub-Pixel Convolutional Neural Network [1]. Here we propose a reimplementation of their method and discuss future applications of the technology.
But first let us discuss some background.
Convolutional neural networks (CNN) are now standard neural network layers for computer vision. Transposed convolutions (sometimes referred to as deconvolution) are the GRADIENTS of a convolutional layer. Transposed convolutions were, as far as we know first used by Zeiler and Fergus [2] for visualization purposes while improving their AlexNet model.
For visualization purposes let us check out that convolutions in the present subject are a sequence of inner product of a given filter (or kernel) with pieces of a larger image. This operation is highly parallelizable, since the kernel is the same throughout the image. People used to refer to convolutions as locally connected layers with shared parameters. Checkout the figure bellow by Dumoulin and Visin [3]:
Note though that convolutional neural networks can be defined with strides
or we can follow the convolution with maxpooling
to
downsample the input image. The equivalent backward
operation of a
convolution with strides, in other words its gradient, is an upsampling
operation, where zeros a filled in between non-zeros pixels followed by a
convolution with the kernel rotated 180 degrees. See representation copied from Dumoulin and
Visin again:
For classification purposes, all that we need is the feedforward pass of a convolutional neural network to extract features at different scales. But for applications such as image super resolution and autoencoders, both downsampling and upsampling operations are necessary in a feedforward pass. The community took inspiration on how the gradients are implemented in CNNs and applied them as a feedforward layer instead.
But as one may have observed the upsampling operation as implemented above with strided convolution gradients adds zero values to the upscale the image, that have to be later filled in with meaningful values. Maybe even worse, these zero values have no gradient information that can be backpropagated through.
To cope with that problem, Shi et. al [1] proposed what we argue to be one the most useful recent convnet tricks (at least in my opinion as a generative model researcher!) They proposed a subpixel convolutional neural network layer for upscaling. This layer essentially uses regular convolutional layers followed by a specific type of image reshaping called a phase shift. In other words, instead of putting zeros in between pixels and having to do extra computation, they calculate more convolutions in lower resolution and resize the resulting map into an upscaled image. This way, no meaningless zeros are necessary. Checkout the figure below from their paper. Follow the colors to have an intuition about how they do the image resizing. Check this paper for further understanding.
Next we will discuss our implementation of this method and later what we foresee to be the implications of it everywhere where upscaling in convolutional neural networks was necessary.
Following Shi et. al. the equation for implementing the phase shift for CNNs is:
In numpy, we can write this as
def PS(I, r):
assert len(I.shape) == 3
assert r>0
r = int(r)
O = np.zeros((I.shape[0]*r, I.shape[1]*r, I.shape[2]/(r*2)))
for x in range(O.shape[0]):
for y in range(O.shape[1]):
for c in range(O.shape[2]):
c += 1
a = np.floor(x/r).astype("int")
b = np.floor(y/r).astype("int")
d = c*r*(y%r) + c*(x%r)
print a, b, d
O[x, y, c-1] = I[a, b, d]
return O
To implement this in Tensorflow we would have to create a custom operator and
its equivalent gradient. But after staring for a few minutes in the image
depiction of the resulting operation we noticed how to write that using just
regular reshape
, split
and concatenate
operations. To understand that
note that phase shift simply goes through different channels of the output
convolutional map and builds up neighborhoods of r x r
pixels. And we can do the
same with a few lines of Tensorflow code as:
def _phase_shift(I, r):
# Helper function with main phase shift operation
bsize, a, b, c = I.get_shape().as_list()
X = tf.reshape(I, (bsize, a, b, r, r))
X = tf.transpose(X, (0, 1, 2, 4, 3)) # bsize, a, b, 1, 1
X = tf.split(1, a, X) # a, [bsize, b, r, r]
X = tf.concat(2, [tf.squeeze(x) for x in X]) # bsize, b, a*r, r
X = tf.split(1, b, X) # b, [bsize, a*r, r]
X = tf.concat(2, [tf.squeeze(x) for x in X]) #
bsize, a*r, b*r
return tf.reshape(X, (bsize, a*r, b*r, 1))
def PS(X, r, color=False):
# Main OP that you can arbitrarily use in you tensorflow code
if color:
Xc = tf.split(3, 3, X)
X = tf.concat(3, [_phase_shift(x, r) for x in Xc])
else:
X = _phase_shift(X, r)
return X
The reminder of this library is an implementation of a subpixel CNN using the proposed PS
implementation for super resolution of celeb-A image faces. The code was written on top of
carpedm20/DCGAN-tensorflow, as so, follow the same instructions to use it:
$ python download.py --dataset celebA # if this doesn't work, you will have to download the dataset by hand somewhere else
$ python main.py --dataset celebA --is_train True --is_crop True
Here we want to forecast that subpixel CNNs are going to ultimately replace transposed convolutions (deconv, conv grad, or whatever you call it) in feedforward neural networks. Phase shift's gradient is much more meaningful and resizing operations are virtually free computationally. Our implementation is a high level one, using default Tensorflow OPs. But next we will rewrite everything with Keras so that an even larger community can use it. Plus, a cuda backend level implementation would be even more appreciated.
But for now we want to encourage the community to experiment replacing deconv layers with subpixel operatinos everywhere. By everywhere we mean:
- Conv-deconv autoencoders
Similar to super-resolution, include subpixel in other autoencoder implementations, replace deconv layers - Style transfer networks
This didn't work in a lazy plug and play in our experiments. We have to look more carefully - Deep Convolutional Autoencoders (DCGAN)
We started doing this, but as predicted we have to change hyperparameters. The network power is totally different from deconv layers. - Segmentation Networks (SegNets)
ULTRA LOW hanging fruit! This one will be the easiest. Free paper, you're welcome! - wherever upscaling is done with zero padding
Join us in the revolution to get rid of meaningless zeros in feedfoward convnets, give suggestions here, try our code!
The top row is the input, the middle row is the output, and the bottom row is the ground truth.
by @dribnet
[1] Real-Time Single Image and Video Super-Resolution Using an Efficient Sub-Pixel Convolutional Neural Network. By Shi et. al.
[2] Visualizing and Understanding Convolutional Networks. By Zeiler and Fergus.
[3] A guide to convolution arithmetic for deep learning. By Dumoulin and Visin.
Alex J. Champandard made a really interesting analysis of this topic in this thread.
For discussions about differences between phase shift and straight up resize
please see the companion notebook and this thread.