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)
you would have
>>> X = np.eye(len(X))
Of course this might not be desirable if you want to learn continuous inputs.
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
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)
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.