Here is a quick experiment to disperse any remaining confusion.

Statistically the weights of a NN-layer follow a distribution that is *usually* close to normal (but not necessarily), but even in the case when trying to sample a perfect normal distribution in practice, there are always computational errors.

Then consider the following experiment:

```
DIM = 1_000_000 # set our dims for weights and input
x = np.ones((DIM,1)) # our input vector
#x = np.random.rand(DIM,1)*2-1.0 # or could also be a more realistic normalized input
probs = [1.0, 0.7, 0.5, 0.3] # define dropout probs
W = np.random.normal(size=(DIM,1)) # sample normally distributed weights
print("W-mean = ", W.mean()) # note the mean is not perfect --> sampling error!
# DO THE DRILL
h = defaultdict(list)
for i in range(1000):
for p in probs:
M = np.random.rand(DIM,1)
M = (M < p).astype(int)
Wp = W * M
a = np.dot(Wp.T, x)
h[str(p)].append(a)
for k,v in h.items():
print("For drop-out prob %r the average linear activation is %r (unscaled) and %r (scaled)" % (k, np.mean(v), np.mean(v)/float(k)))
```

Sample output:

```
x-mean = 1.0
W-mean = -0.001003985674840264
For drop-out prob '1.0' the average linear activation is -1003.985674840258 (unscaled) and -1003.985674840258 (scaled)
For drop-out prob '0.7' the average linear activation is -700.6128015029908 (unscaled) and -1000.8754307185584 (scaled)
For drop-out prob '0.5' the average linear activation is -512.1602655283492 (unscaled) and -1024.3205310566984 (scaled)
For drop-out prob '0.3' the average linear activation is -303.21194422742315 (unscaled) and -1010.7064807580772 (scaled)
```

Notice that the unscaled activations diminish due to the *statistically imperfect normal distribution*.

Can you spot an obvious correlation between the `W-mean`

and the average linear activation means?

weight scaling inference rule. – Lerner Zhang Sep 8 '18 at 6:32