Since there is already an answer that provides a workaround I'm going to focus on problems with your approach.

## Input data scale

As others have stated, your input data value range from 0 to 1000 is quite big. This problem can be easily solved by scaling your input data to zero mean and unit variance (`X = (X - X.mean())/X.std()`

) which will result in improved training performance. For `tanh`

this improvement can be explained by saturation: `tanh`

maps to [-1;1] and will therefore return either -1 or 1 for almost all sufficiently big (>3) `x`

, i.e. it saturates. In saturation the gradient for `tanh`

will be close to zero and nothing will be learned. Of course, you could also use `ReLU`

instead, which won't saturate for values > 0, however you will have a similar problem as now gradients depend (almost) solely on `x`

and therefore later inputs will always have higher impact than earlier inputs (among other things).

While re-scaling or normalization may be a solution, another solution would be to treat your input as a categorical input and map your discrete values to a one-hot encoded vector, so instead of

```
>>> X = np.arange(T)
>>> X.shape
(1000,)
```

you would have

```
>>> X = np.eye(len(X))
>>> X.shape
(1000, 1000)
```

Of course this might not be desirable if you want to learn continuous inputs.

## Modeling

You are currently trying to model a mapping from a linear function to a non-linear function: you map `f(x) = x`

to `g(x) = sin(x)`

. While I understand that this is a toy problem, this way of modeling is limited to only this one curve as `f(x)`

is in no way related to `g(x)`

. As soon as you are trying to model different curves, say both `sin(x)`

and `cos(x)`

, with the same network you will have a problem with your `X`

as it has exactly the same values for both curves. A better approach of modeling this problem is to **predict the next value** of the curve, i.e. instead of

```
X = range(T)
Y = sin(x)
```

you want

```
X = sin(X)[:-1]
Y = sin(X)[1:]
```

so for time-step 2 you will get the `y`

value of time-step 1 as input and your loss expects the `y`

value of time-step 2. This way you implicitly model time.