## The noise shape

In order to understand `SpatialDropout1D`

, you should get used to the notion of the **noise shape**. In plain vanilla dropout, each element is kept or dropped independently. For example, if the tensor is `[2, 2, 2]`

, each of 8 elements can be zeroed out depending on random coin flip (with certain "heads" probability); in total, there will be 8 independent coin flips and any number of values may become zero, from `0`

to `8`

.

Sometimes there is a need to do more than that. For example, one may need to drop the *whole slice* along `0`

axis. The `noise_shape`

in this case is `[1, 2, 2]`

and the dropout involves only 4 independent random coin flips. The first component will either be kept together or be dropped together. The number of zeroed elements can be `0`

, `2`

, `4`

, `6`

or `8`

. It cannot be `1`

or `5`

.

Another way to view this is to imagine that input tensor is in fact `[2, 2]`

, but each value is double-precision (or multi-precision). Instead of dropping the bytes in the middle, the layer drops the full multi-byte value.

## Why is it useful?

The example above is just for illustration and isn't common in real applications. More realistic example is this: `shape(x) = [k, l, m, n]`

and `noise_shape = [k, 1, 1, n]`

. In this case, each batch and channel component will be kept independently, but each row and column will be kept or not kept together. In other words, the *whole* `[l, m]`

*feature map* will be either kept or dropped.

You may want to do this to account for adjacent pixels correlation, especially in the early convolutional layers. Effectively, you want to prevent co-adaptation of pixels with its neighbors across the feature maps, and make them learn as if no other feature maps exist. This is exactly what `SpatialDropout2D`

is doing: it promotes independence between feature maps.

The `SpatialDropout1D`

is very similar: given `shape(x) = [k, l, m]`

it uses `noise_shape = [k, 1, m]`

and drops entire 1-D feature maps.

Reference: Efficient Object Localization Using Convolutional Networks
by Jonathan Tompson at al.