True - ReLU is designed to result in zero for negative values. (It can be dangerous with big learning rates, bad initialization or with very few units - all neurons can get stuck in zero and the model freezes)

False - Sigmoid results in zero for "very negative" inputs, not for "negative" inputs. If your inputs are between -3 and +3, you will see a very pleasant result between 0 and 1.

False - The same comment as Sigmoid. If your inputs are between -2 and 2, you will see nice results between -1 and 1.

So, the saturation problem only exists for inputs whose absolute values are too big.

By definition, the outputs are:

- ReLU: 0 < y < inf (with center in 0)
- Sigmoid: 0 < y < 1 (with center in 0.5)
- TanH: -1 < y < 1 (with center in 0)

You might want to use a `BatchNormalization`

layer before these activations to avoid having big values and avoid saturation.

For predicting negative outputs, `tanh`

is the only of the three that is capable of doing that.

You could invent a negative sigmoid, though, it's pretty easy:

```
def neg_sigmoid(x):
return -keras.backend.sigmoid(x)
#use the layer:
Activation(neg_sigmoid)
```