I built a convolutional neural network in Keras.

```
model.add(Convolution1D(nb_filter=111, filter_length=5, border_mode='valid', activation="relu", subsample_length=1))
```

According to the CS231 lecture a convolving operation creates a feature map (i.e. activation map) for each filter which are then stacked together. IN my case the convolutional layer has a 300 dimensional input. Hence, I expect the following computation:

- Each filter has a window size of 5. Consequently, each filter produces 300-5+1=296 convolutions.
- As there are 111 filters there should be a 111*296 output of the convolutional layer.

However, the actual output shapes look differently:

```
convolutional_layer = model.layers[1]
conv_weights, conv_biases = convolutional_layer.get_weights()
print(conv_weights.shape) # (5, 1, 300, 111)
print(conv_biases.shape) # (,111)
```

The shape of the bias values makes sense, because there is one bias value for each filter. However, I do not understand the shape of the weights. Apparently, the first dimension depends on the filter size. The third dimension is the number of input neurons, which should have been reduced by the convolution. The last dimension probably refers to the number of filters. This does not make sense, because how should I easily get the feature map for a specific filter?

Keras either uses Theano or Tensorflow as a backend. According to their documentation the output of a convolving operation is a 4d tensor (batch_size, output_channel, output_rows, output_columns).

Can somebody explain me the output shape in accordance with the CS231 lecture?

`model.summary()`

. But, perhaps you've got inverted dimensions in the "input": (channels x 1d length) versus (1d length x channels). Try inverting the input, with "Reshape((1,300))" or "Reshape((300,1))" -- It will depend on whether your keras is configured for channels first or channels last. (Also, I don't know what the`subsample_length=1`

means, it's not on keras documentation, it seems). – Daniel Möller May 8 '17 at 14:32