## What a Flatten layer does

After convolutional operations, `tf.keras.layers.Flatten`

will reshape a tensor into `(n_samples, height*width*channels)`

, for example turning `(16, 28, 28, 3)`

into `(16, 2352)`

. Let's try it:

```
import tensorflow as tf
x = tf.random.uniform(shape=(100, 28, 28, 3), minval=0, maxval=256, dtype=tf.int32)
flat = tf.keras.layers.Flatten()
flat(x).shape
```

```
TensorShape([100, 2352])
```

## What a GlobalAveragePooling layer does

After convolutional operations, `tf.keras.layers.GlobalAveragePooling`

layer does is average all the values *according to the last axis*. This means that the resulting shape will be `(n_samples, last_axis)`

. For instance, if your last convolutional layer had 64 filters, it would turn `(16, 7, 7, 64)`

into `(16, 64)`

. Let's make the test, after a few convolutional operations:

```
import tensorflow as tf
x = tf.cast(
tf.random.uniform(shape=(16, 28, 28, 3), minval=0, maxval=256, dtype=tf.int32),
tf.float32)
gap = tf.keras.layers.GlobalAveragePooling2D()
for i in range(5):
conv = tf.keras.layers.Conv2D(64, 3)
x = conv(x)
print(x.shape)
print(gap(x).shape)
```

```
(16, 24, 24, 64)
(16, 22, 22, 64)
(16, 20, 20, 64)
(16, 18, 18, 64)
(16, 16, 16, 64)
(16, 64)
```

## Which should you use?

The `Flatten`

layer will always have at least as much parameters as the `GlobalAveragePooling2D`

layer. If the final tensor shape before flattening is still large, for instance `(16, 240, 240, 128)`

, using `Flatten`

will make an insane amount of parameters: `240*240*128 = 7,372,800`

. This huge number will be multiplied by the number of units in your next dense layer! At that moment, `GlobalAveragePooling2D`

might be preferred in most cases. If you used `MaxPooling2D`

and `Conv2D`

so much that your tensor shape before flattening is like `(16, 1, 1, 128)`

, it won't make a difference. If you're overfitting, you might want to try `GlobalAveragePooling2D`

.