Sorry for this simple question.
How do i calculate simple derivative for function y=x^2+1
using Numpy?
UPDATE: let's say, i want the value of derivative at x=5

You have four options
Finite differences require no external tools but are prone to numerical error and, if you're in a multivariate situation, can take a while. Symbolic differentiation is ideal if your problem is simple enough. Symbolic methods are getting quite robust these days. SymPy is an excellent project for this that integrates well with NumPy. Look at the autowrap or lambdify functions or check out Jensen's blogpost about a similar question. Automatic derivatives are very cool, aren't prone to numeric errors, but do require some additional libraries (google for this, there are a few good options). This is the most robust but also the most sophisticated/difficult to set up choice. If you're fine restricting yourself to Here is an example using SymPy



NumPy does not provide general functionality to compute derivatives. It can handles the simple special case of polynomials however:
If you want to compute the derivative numerically, you can get away with using central difference quotients for the vast majority of applications. For the derivative in a single point, the formula would be something like
if you have an array



The topic of numerical differentiation is quite 'large' and there are many ways of calculating such derivatives entirely numerically. I leave it to you to follow the previous link and figure out if and how to apply such techniques to your problems. 


See this link, using Scipy http://docs.scipy.org/doc/scipy/reference/generated/scipy.misc.derivative.html You can find your answer 


SymPy can supposedly do symbolic mathematics: http://code.google.com/p/sympy/ Maybe you just need to add another library over and above NumPy. 


Depending on the level of precision you require you can work it out yourself, using the simple proof of differentiation:
we can't actually take the limit of the gradient, but its kinda fun. You gotta watch out though because



The most straightforward way I can think of is using numpy's gradient function:
This way, dydx will be computed using central differences and will have the same length as y, unlike numpy.diff, which uses forward differences and will return (n1) size vector. 

