# python scipy convolve2d seems incorrect

my aim is to create and visualize the partial derivatives of a image (2D). I´ll do this with the first finite central difference equation wikipedia .

the partial derivative of F with respect to x is

df(x,y)/dx=f(x+1,y)-f(x-1,y)

we can write this as a convolve kernel H=[-1,0,1] and should get the same result by convolve the image with the kernel

dfx=F*H

Here is my source-code:

from numpy import *
from pylab import *
from PIL import *
from scipy import signal as sg

#create artifical image with constant positive slope
myImage=zeros((5,5),dtype=float)
for y in range(5):
for x in range(5):
myImage[y,x]=y+x


at first I create the first central finite difference for x and y by the convolve2d - function from the scipy modul (the short way)

kernel=array([[-1,0,1]])     #create first central finite difference kernel
pdx=sg.convolve2d(myImage,kernel,"same")   #dI(x,y)/dx


and now I create the same using loops

H,W=myImage.shape[0:2]
pdx=zeros((H,W),dtype=float)
for y in range(1,H-1):
for x in range(1,W-1):
pdx.itemset(y,x,im.item(y,x+1)-im.item(y,x-1))


Let´s see the results:

pdx - kernel method by convolve2d

array([[-1., -2., -2., -2.,  3.],
[-2., -2., -2., -2.,  4.],
[-3., -2., -2., -2.,  5.],
[-4., -2., -2., -2.,  6.],
[-5., -2., -2., -2.,  7.]])


pdx - finite difference by loops

array([[ 0.,  0.,  0.,  0.,  0.],
[ 0.,  2.,  2.,  2.,  0.],
[ 0.,  2.,  2.,  2.,  0.],
[ 0.,  2.,  2.,  2.,  0.],
[ 0.,  0.,  0.,  0.,  0.]])


I´m confused about the results. Why has the kernel method a negative slope ? To get the same results i have to flip the kernel to H=[1,0,-1], but this is mathematically not correct. Can someone help me ?

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As a sidenote, you can create myImage much faster with broadcasting: x = np.arange(5.) myImage = x[:, None] + x –  askewchan Nov 19 '13 at 17:38
An aside: Note that your convolution kernel H=[1, 0, -1] is a modified Prewitt operator (en.wikipedia.org/wiki/Prewitt_operator) for which scipy.ndimage has a handy call. –  BrianTheLion Mar 5 at 22:08

The reason for the difference is two-fold:

1. You've forgotten the flipping of the kernel in the mathematical definition of a convolution.
2. You're assuming different boundary conditions than scipy.signal

Also, for what you're doing, you almost definitely want scipy.ndimage.convolve instead of scipy.signal.convolve2d. The defaults for ndimage are set up to work with images, and it's more efficient for limited-precision integer data, which is the norm for images.

To reproduce your loop version with scipy.signal, you'd need to reverse the kernel, as you've noticed.

This is the mathematical definition of a convolution. The kernel is flipped before being "swept by". For example: http://en.wikipedia.org/wiki/File:Convolution3.PNG

Second, scipy.signal.convolve2d pads the boundaries with zeros by default, while you're simply not operating on the boundaries. To reproduce your boundary conditions with scipy.signal.convolve2d, use boundary='symm' (For this specific kernel, anyway... In general, you're just ignoring the boundaries, which convolve2d doesn't have an option for.)

Finally, for your purposes (image processing), it's far more efficient to use scipy.ndimage.convolve. In this case (a 1D kernel), it's most efficient to use scipy.ndimage.convolve1d. E.g. scipy.ndimage.convolve1d(data, [1, 0, -1], axis=0)

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Convolution of f and g is the integral of f(x') g(x - x') over dx'. The effect of this is that the kernel is flipped. Either use the flipped kernel, or use scipy.ndimage.correlate which does f(x') g(x + x'), so the kernel is kept in the same direction as input.