# Python finite difference functions?

I've been looking around in Numpy/Scipy for modules containing finite difference functions. However, the closest thing I've found is `numpy.gradient()`, which is good for 1st-order finite differences of 2nd order accuracy, but not so much if you're wanting higher-order derivatives or more accurate methods. I haven't even found very many specific modules for this sort of thing; most people seem to be doing a "roll-your-own" thing as they need them. So my question is if anyone knows of any modules (either part of Numpy/Scipy or a third-party module) that are specifically dedicated to higher-order (both in accuracy and derivative) finite difference methods. I've got my own code that I'm working on, but it's currently kind of slow, and I'm not going to attempt to optimize it if there's something already available.

Note that I am talking about finite differences, not derivatives. I've seen both `scipy.misc.derivative()` and Numdifftools, which take the derivative of an analytical function, which I don't have.

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Would interpolating the data and then using `scipy.misc.derivative` on the interpolation function work for you? –  unutbu Sep 24 '13 at 21:03
Take a look at `numpy.diff` (docs.scipy.org/doc/numpy/reference/generated/numpy.diff.html). –  Warren Weckesser Sep 24 '13 at 21:26
Also, if your data is periodic, there is `scipy.fftpack.diff` (docs.scipy.org/doc/scipy/reference/generated/…). There is an example of its use here: wiki.scipy.org/Cookbook/KdV –  Warren Weckesser Sep 24 '13 at 21:32
@unutbu: I guess in theory it could work, if I'm reading the documentation correctly, by setting the dx parameter to be the same as the grid spacing and forcing x0 to be at one of the grid points. However, my intent is to use this for 2- and 3- dimensional arrays, so for an MxNxP array, I'd have to create NxP interp1d objects for a derivative in the M direction, which seems a little slow. It would also require a Python loop, which I'd like to avoid, for the same reason. –  Tim Supinie Sep 24 '13 at 21:32
@askewchan: Accuracy here refers to error in the finite difference approximation resulting from the truncation of the Taylor series. More accurate finite difference methods keep around more terms of the Taylor series, and are therefore closer to the true derivative at that point. 1st order keeps around fewer terms than 2nd order, and so on. –  Tim Supinie Sep 24 '13 at 22:18

One way to do this quickly is by convolution with the derivative of a gaussian kernel. The simple case is a convolution of your array with `[-1, 1]` which gives exactly the simple finite difference formula. Beyond that, `(f*g)'= f'*g = f*g'` where the `*` is convolution, so you end up with your derivative convolved with a plain gaussian, so of course this will smooth your data a bit, which can be minimized by choosing the smallest reasonable kernel.

``````import numpy as np
from scipy import ndimage
import matplotlib.pyplot as plt

#Data:
x = np.linspace(0,2*np.pi,100)
f = np.sin(x) + .02*(np.random.rand(100)-.5)

#Normalization:
dx = x[1] - x[0] # use np.diff(x) if x is not uniform
dxdx = dx**2

#First derivatives:
df = np.diff(f) / dx
cf = np.convolve(f, [1,-1]) / dx
gf = ndimage.gaussian_filter1d(f, sigma=1, order=1, mode='wrap') / dx

#Second derivatives:
ddf = np.diff(f, 2) / dxdx
ccf = np.convolve(f, [1, -2, 1]) / dxdx
ggf = ndimage.gaussian_filter1d(f, sigma=1, order=2, mode='wrap') / dxdx

#Plotting:
plt.figure()
plt.plot(x, f, 'k', lw=2, label='original')
plt.plot(x[:-1], df, 'r.', label='np.diff, 1')
plt.plot(x, cf[:-1], 'r--', label='np.convolve, [1,-1]')
plt.plot(x, gf, 'r', label='gaussian, 1')
plt.plot(x[:-2], ddf, 'g.', label='np.diff, 2')
plt.plot(x, ccf[:-2], 'g--', label='np.convolve, [1,-2,1]')
plt.plot(x, ggf, 'g', label='gaussian, 2')
``````

Since you mentioned `np.gradient` I assumed you had at least 2d arrays, so the following applies to that: This is built into the `scipy.ndimage` package if you want to do it for ndarrays. Be cautious though, because of course this doesn't give you the full gradient but I believe the product of all directions. Someone with better expertise will hopefully speak up.

Here's an example:

``````from scipy import ndimage

x = np.linspace(0,2*np.pi,100)
sine = np.sin(x)

im = sine * sine[...,None]
d1 = ndimage.gaussian_filter(im, sigma=5, order=1, mode='wrap')
d2 = ndimage.gaussian_filter(im, sigma=5, order=2, mode='wrap')

plt.figure()

plt.subplot(131)
plt.imshow(im)
plt.title('original')

plt.subplot(132)
plt.imshow(d1)
plt.title('first derivative')

plt.subplot(133)
plt.imshow(d2)
plt.title('second derivative')
``````

Use of the `gaussian_filter1d` allows you to take a directional derivative along a certain axis:

``````imx = im * x
d2_0 = ndimage.gaussian_filter1d(imx, axis=0, sigma=5, order=2, mode='wrap')
d2_1 = ndimage.gaussian_filter1d(imx, axis=1, sigma=5, order=2, mode='wrap')

plt.figure()
plt.subplot(131)
plt.imshow(imx)
plt.title('original')
plt.subplot(132)
plt.imshow(d2_0)
plt.title('derivative along axis 0')
plt.subplot(133)
plt.imshow(d2_1)
plt.title('along axis 1')
``````

The first set of results above are a little confusing to me (peaks in the original show up as peaks in the second derivative when the curvature should point down). Without looking further into how the 2d version works, I can only really recomend the 1d version. If you want the magnitude, simply do something like:

``````d2_mag = np.sqrt(d2_0**2 + d2_1**2)
``````
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Thanks for this answer. Regarding `cf[:-1]/cf.max()`: This seems to be using a prior knowledge that the maximum derivative should be 1. To generalize the calculation for data with no a prior knowledge, I think you would need to replace that with `cf = np.convolve(f, [1,-1], mode='same')/(x[1]-x[0])`. –  unutbu Nov 18 '13 at 12:56
Actually, if I recall correctly I only did that for plotting purposes: to compare `convolve` qualitatively with `diff` for both the first and second order on the same plot without worrying about scale. Clearly using `max` is not usually the proper normalization; `dx` is. I'll try to fix it soon :) –  askewchan Nov 18 '13 at 17:34
+1 for complete answer. –  Neerav Jan 16 at 19:17