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I am newbie in convolutional neural networks and just have idea about feature maps and how convolution is done on images to extract features. I would be glad to know some details on applying batch normalisation in CNN.

I read this paper https://arxiv.org/pdf/1502.03167v3.pdf and could understand the BN algorithm applied on a data but in the end they mentioned that a slight modification is required when applied to CNN:

For convolutional layers, we additionally want the normalization to obey the convolutional property – so that different elements of the same feature map, at different locations, are normalized in the same way. To achieve this, we jointly normalize all the activations in a mini- batch, over all locations. In Alg. 1, we let B be the set of all values in a feature map across both the elements of a mini-batch and spatial locations – so for a mini-batch of size m and feature maps of size p × q, we use the effec- tive mini-batch of size m′ = |B| = m · pq. We learn a pair of parameters γ(k) and β(k) per feature map, rather than per activation. Alg. 2 is modified similarly, so that during inference the BN transform applies the same linear transformation to each activation in a given feature map.

I am total confused when they say "so that different elements of the same feature map, at different locations, are normalized in the same way"

I know what feature maps mean and different elements are the weights in every feature map. But I could not understand what location or spatial location means.

I could not understand the below sentence at all "In Alg. 1, we let B be the set of all values in a feature map across both the elements of a mini-batch and spatial locations"

I would be glad if someone cold elaborate and explain me in much simpler terms

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Let's start with the terms. Remember that the output of the convolutional layer is a 4-rank tensor [B, H, W, C], where B is the batch size, (H, W) is the feature map size, C is the number of channels. An index (x, y) where 0 <= x < H and 0 <= y < W is a spatial location.

Usual batchnorm

Now, here's how the batchnorm is applied in a usual way (in pseudo-code):

# t is the incoming tensor of shape [B, H, W, C]
# mean and stddev are computed along 0 axis and have shape [H, W, C]
mean = mean(t, axis=0)
stddev = stddev(t, axis=0)
for i in 0..B-1:
  out[i,:,:,:] = norm(t[i,:,:,:], mean, stddev)

Basically, it computes H*W*C means and H*W*C standard deviations across B elements. You may notice that different elements at different spatial locations have their own mean and variance and gather only B values.

Batchnorm in conv layer

This way is totally possible. But the convolutional layer has a special property: filter weights are shared across the input image (you can read it in detail in this post). That's why it's reasonable to normalize the output in the same way, so that each output value takes the mean and variance of B*H*W values, at different locations.

Here's how the code looks like in this case (again pseudo-code):

# t is still the incoming tensor of shape [B, H, W, C]
# but mean and stddev are computed along (0, 1, 2) axes and have just [C] shape
mean = mean(t, axis=(0, 1, 2))
stddev = stddev(t, axis=(0, 1, 2))
for i in 0..B-1, x in 0..H-1, y in 0..W-1:
  out[i,x,y,:] = norm(t[i,x,y,:], mean, stddev)

In total, there are only C means and standard deviations and each one of them is computed over B*H*W values. That's what they mean when they say "effective mini-batch": the difference between the two is only in axis selection (or equivalently "mini-batch selection").

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    Great answer, but I think you mean that we should take the mean and variance of B*H*W values, not B*H*C values. Refer to the first paragraph after Batchnorm in conv layer. Either way, +1. – rayryeng Nov 19 '17 at 18:47
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    @rayryeng thanks, a typo indeed, corrected. – Maxim Nov 20 '17 at 9:47
  • Could we not just write: out[:,:,:,:] = norm(t[:,:,:,:], mean, stddev) without the loop? The mean and variance are computed over the whole batch and then it is applied to each element in the batch seperately rather than at once? @maxim – palimboa Jun 28 '18 at 10:14
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I'm only 70% sure of what I say, so if it does not make sense, please edit or mention it before downvoting.

About location or spatial location: they mean the position of pixels in an image or feature map. A feature map is comparable to a sparse modified version of image where concepts are represented.

About so that different elements of the same feature map, at different locations, are normalized in the same way: some normalisation algorithms are local, so they are dependent of their close surrounding (location) and not the things far apart in the image. They probably mean that every pixel, regardless of their location, is treated just like the element of a set, independently of it's direct special surrounding.

About In Alg. 1, we let B be the set of all values in a feature map across both the elements of a mini-batch and spatial locations: They get a flat list of every values of every training example in the minibatch, and this list combines things whatever their location is on the feature map.

  • Just wanted to clear my idea with an example. So basically if we have 10 feature maps of size 5x5 and mini batch size of 20 so do we try to normalise every feature map individually? So the new mini batch size is = 20 * 25.(25 because the feature map is of size 5x5). I am confused if individual feature map is normalised with its own mean and variance or the mean and variance is the same for all the 10 feature maps. If the latter is the case what will be the new updated mini batch size? – akshata bhat Jul 25 '16 at 11:21

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