I am trying to use 3d conv on cifar10 data set (just for fun). I see the docs that we usually have the input be 5d tensors (N,C,D,H,W). Am I really forced to pass 5 dimensional data necessarily?

The reason I am skeptical is because 3D convolutions simply mean my conv moves across 3 dimensions/directions. So technically I could have 3d 4d 5d or even 100d tensors and then should all work as long as its at least a 3d tensor. Is that not right?

I tried it real quick and it did give an error:

import torch
def conv3d_example():
    N,C,H,W = 1,3,7,7
    img = torch.randn(N,C,H,W)
    in_channels, out_channels = 1, 4
    kernel_size = (2,3,3)
    conv = torch.nn.Conv3d(in_channels, out_channels, kernel_size)
    out = conv(img)
RuntimeError                              Traceback (most recent call last)
<ipython-input-3-29c73923cc64> in <module>
     16 ##
---> 17 conv3d_example()

<ipython-input-3-29c73923cc64> in conv3d_example()
     10     conv = torch.nn.Conv3d(in_channels, out_channels, kernel_size)
     11     ##
---> 12     out = conv(img)
     13     print(out)
     14     print(out.size())

~/anaconda3/lib/python3.7/site-packages/torch/nn/modules/module.py in __call__(self, *input, **kwargs)
    491             result = self._slow_forward(*input, **kwargs)
    492         else:
--> 493             result = self.forward(*input, **kwargs)
    494         for hook in self._forward_hooks.values():
    495             hook_result = hook(self, input, result)

~/anaconda3/lib/python3.7/site-packages/torch/nn/modules/conv.py in forward(self, input)
    474                             self.dilation, self.groups)
    475         return F.conv3d(input, self.weight, self.bias, self.stride,
--> 476                         self.padding, self.dilation, self.groups)

RuntimeError: Expected 5-dimensional input for 5-dimensional weight 4 1 2 3, but got 4-dimensional input of size [1, 3, 7, 7] instead

cross posted:


Consider the following scenario. You have a 3 channel NxN image. This image will have size of 3xNxN in pytorch (ignoring the batch dimension for now).

Say you pass this image to a 2D convolution layer with no bias, kernel size 5x5, padding of 2, and input/output channels of 3 and 10 respectively.

What's actually happening when we apply this layer to the input image?

You can think of it like this...

For each of the 10 output channels there is a kernel of size 3x5x5. A 3D convolution is applied to the 3xNxN input image using this kernel, which can be thought of as unpadded in the first dimension. The result of this convolution is a 1xNxN feature map.

Since there are 10 output layers, there are 10 of the 3x5x5 kernels. After all kernels have been applied the outputs are stacked into a single 10xNxN tensor.

So really, in the classical sense, a 2D convolution layer is already performing a 3D convolution.

Similarly for a 3D convolution layer, its really doing a 4D convolution, which is why you need 5 dimensional input.

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