enter image description here

The animation is from here. I am wondering why the dilated convolution is claimed to preserve resolution. Apparently the input in blue is 7x7 and the output in green is 3x3.


One way to work around the resolution loss is to pad the input with roughly half the size of the current receptive field, but

  1. this essentially undermines the statement that dilated convolutions do not lose resolution, because it is the padding that preserves the resolution. To get the same output size with the input, a conventional convolution needs even less padding.
  2. since the padding grows exponentially, a relative not-that-small dilation factor will leads to a heavily padded input image. Imagine a 1024x1024 input with 10x dilation, it will become about 2048x2048 (please let me know if I am wrong here). This is 4x the original size, which means most of the convolutions are done on the padded area instead of the real input. Personally this seems quite counterintuitive to me.

1 Answer 1


This is indeed a dilated convolution with a 5x5 filter. If you imagine the blue part of the animation as a 3x3 image that's 0 padded, it preserves resolution.

With regard to your edit, the emphasis is really in this statement in the post you linked: dilated convolutions support exponential expansion of the receptive field without loss of resolution or coverage

Padding is done to preserve resolution. That is correct.

What we really want here is to expand the size of the receptive field. In the post you linked, with 3 3x3 dilated convolutions at an increasing dilation, we already achieve a receptive field of 15x15 in the feature maps.

To achieve the equivalent with 3x3 convolutions and no loss of coverage and no loss of resolution, we can do it with a stride of 3 (4 would result in loss of coverage) and extremely heavy padding (to the extent where it's like what you said, convolution with mostly padded zeroes). However, we will need 4 3x3 convolutions with stride 3 instead of 3 to achieve a receptive field of 15x15.

On top of that, the normal convolutions would have even more convolutions that don't make sense, compared to the dilated convolution case.

  • That makes sense but means the padding also grows exponentially, right?
    – wlnirvana
    Aug 23, 2017 at 13:40
  • Yes. But the amount of computation is still the same. I think most libraries would optimize such operations and do it on sparse matrices and not actually have to pad and store it in memory.
    – jkschin
    Aug 23, 2017 at 13:43
  • Please see my edit above in the question. Btw thanks for the quick response :)
    – wlnirvana
    Aug 23, 2017 at 14:17
  • Hmm... let me rephrase to see if I understand it. So the tradeoff is: If only convs with stride 1 are used, padding is small but we will need too many layers (thus too many params/weights) to preserve resolution. If convs with a large stride are used, we face the same problem of heavy padding, and still need more layers. Thus the dilated convolution is kind of a better balanced choice.
    – wlnirvana
    Aug 23, 2017 at 14:43
  • So any way as I understood we do dilated convnets to capture more global context while capturing the local. So here with padding we make sure we don't miss any neurons in the feature maps . Am I right ? Sep 26, 2017 at 16:55

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