in a given application I apply an averaging mask to input images to reduce noise, and then a Laplacian mask to enhance small details. Anyone knows if I Would get the same results if I reverse the order of these operations in Matlab?
Convolving with a Laplacian kernel is similar to using second derivative information about the intensity changes. Since this derivative is sensitive to noise, we often smooth the image with a Gaussian before applying the Laplacian filter.
Here's a MATLAB example similar to what @belisarius posted:
Lets say you have two filters
Where here I am using
By the associative rule of convolution, this is the same as.
using commutativity, we can say that
Of course, this is in the nice continuous domain of math, doing these things on a machine means there will be rounding errors and some data may be lost. You also should think about if your filters are FIR, otherwise the whole concept of thinking about digital filtering as convolution sorta starts to break down as your filter can't really behave the way you wanted it to.
The discrete convolution is defined as
so adding zeros at the edges of you data doesn't change anything in a mathematical sense.
As some people have pointed out, you will get different answers numerically, but this is expected whenever we deal with computing actual data. These variations should be small and limited to the low energy components of the output of the convolution (i.e: the edges).
It is also important to consider how the convolution operation is working. Convolving two sets of data of length
So in regards to @belisarius' post, it would seem we are really saying the same thing.
Numerically the results are not the same, but the images look pretty similar.
Example in Mathematica:
As an answer to @thron comment in his answer about commutation of linear filters and padding, just consider the following operations.
While commutation of a Gaussian and Laplacian filter without padding is true:
Doing the same with padding, result in a difference at the edges: