I really can not understand what numpy.gradient function does and how to use it for computation of multivariable function gradient.

For example, I have such a function:

def func(q, chi, delta):
    return q * chi * delta

I need to compute it's 3-dimensional gradient (in other words, I want to compute partial derivatives with respect to all variables (q, chi, delta)).

How can I calculate this gradient using NumPy?


The problem is, that numpy can't give you the derivatives directly and you have two options:


What you essentially have to do, is to define a grid in three dimension and to evaluate the function on this grid. Afterwards you feed this table of function values to numpy.gradient to get an array with the numerical derivative for every dimension (variable).

Example from here:

from numpy import *

x,y,z = mgrid[-100:101:25., -100:101:25., -100:101:25.]

V = 2*x**2 + 3*y**2 - 4*z # just a random function for the potential

Ex,Ey,Ez = gradient(V)

Without NUMPY

You could also calculate the derivative yourself by using the centered difference quotient. centered difference quotient

This is essentially, what numpy.gradient is doing for every point of your predefined grid.

  • Thanks,Stefan! In fact I understand how to compute derivatives manualy (without any framework), but I was not able to understand how np.gradient works. Previously I'd used for this purpose combination of C++ with gsl, but this approach requires too much coding. – Mikhail Elizarev Apr 19 '13 at 12:44
  • 2
    To be precise, the formula is what numpy.diff does; numpy.gradient is similar but has special behaviour at boundaries. – Mark Oct 28 '14 at 11:08
  • @Mark: numpy.gradient is much more like like this formula (centered difference quotient with $+\Delta x$ and $-\Delta x$) than numpy.diff – user66081 Aug 3 '16 at 11:23
  • 1
    They are both quite similar. gradient indeed uses the central difference at the grid points, which is similar, but treats the boundaries differently. diff could be said to get the central difference in the middle between the grid point (with delta half a grid spacing), and doesn't treat boundaries specially but just makes the gradient grid 1 point smaller. They both follow the expression, but with different evaluation points and deltas, and with different boundary behaviour. Since the answer doesn't mention how to treat any of that, I guess it's subjective which is more similar... – Mark Aug 11 '16 at 2:07

Numpy and Scipy are for numerical calculations. Since you want to calculate the gradient of an analytical function, you have to use the Sympy package which supports symbolic mathematics. Differentiation is explained here (you can actually use it in the web console in the left bottom corner).

You can install Sympy under Ubuntu with

sudo apt-get install python-sympy

or under any Linux distribution with pip

sudo pip install sympy

Also theano can compute the gradient automatically



You could use scipy.optimize.approx_fprime

f = lambda x: x**2
approx_fprime(np.array([2]), f, epsilon=1e-6)  # array([ 4.000001])

Numpy doesn't directly support gradient calculations without creating an entire grid of points. Instead, I would use autodifferentiation See https://code.activestate.com/recipes/580610-auto-differentiation/ for how to do it in Python.

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