Instead of using a `Flatten`

layer, you could use a **Global Pooling** layer.

These are suited to collapse the length/time dimension without losing the capability of using variable lengths.

So, instead of `Flatten()`

, you can try a `GlobalAveragePooling1D`

or `GlobalMaxPooling1D`

.

None of them use `supports_masking`

in their code, so they must be used with care.

The average one will consider more inputs than the max (thus the values that should be masked).

The max will take only one from the length. With luck, if all your useful values are higher than the ones in the masked position, it will indirectly preserve the mask. It will probably need even more input neurons than the other.

That said, yes, try the `Conv1D`

or RNN (`LSTM`

) appoaches suggested.

## Creating a custom pooling layer with mask

You can also create your own pooling layer (needs a functional API model where you pass both the model's inputs and the tensor which you want to pool)

Below, a working example with average pooling applying a mask based on the inputs:

```
def customPooling(maskVal):
def innerFunc(x):
inputs = x[0]
target = x[1]
#getting the mask by observing the model's inputs
mask = K.equal(inputs, maskVal)
mask = K.all(mask, axis=-1, keepdims=True)
#inverting the mask for getting the valid steps for each sample
mask = 1 - K.cast(mask, K.floatx())
#summing the valid steps for each sample
stepsPerSample = K.sum(mask, axis=1, keepdims=False)
#applying the mask to the target (to make sure you are summing zeros below)
target = target * mask
#calculating the mean of the steps (using our sum of valid steps as averager)
means = K.sum(target, axis=1, keepdims=False) / stepsPerSample
return means
return innerFunc
x = np.ones((2,5,3))
x[0,3:] = 0.
x[1,1:] = 0.
print(x)
inputs = Input((5,3))
out = Lambda(lambda x: x*4)(inputs)
out = Lambda(customPooling(0))([inputs,out])
model = Model(inputs,out)
model.predict(x)
```