I currently have a large matrix M (~100x100x50 elements) containing both positive and negative values. At the moment, if I want to smooth this matrix, I use the smooth3 function to apply a gaussian kernel over the entire 3-D matrix.

What I want to achieve is a variable level of smoothing within this matrix - i.e.. different parts of the matrix M are smoothed to different levels of sigma depending of the value in a similar 3-D matrix, d (with values ranging from 0 to 1). Where d is 0, no smoothing occurs, where d is 1 a maximum level of smoothing occurs.

The fact that the matrix is 3-D is trivial. Smoothing in 3 dimensions is nice, but not essential, and my current code (performing various other manipulations) handles each of the 50 slices of M separately anyway. I am happy to replace smooth3 with a convolution of M with a gaussian function, and perform this convolution over each slice individually. What I can't figure out is how to vary the sigma level of this gaussian function (based on d) given its location in M and output the result accordingly.

An alternative approach may be to use matrix d as a mask for a very smooth version of matrix Ms and somehow manipulate M and Ms to give an equivalent result, however I'm not convinced that this will work as I can't think of a function to combine M and Md that won't give artefacts of each of M or Ms when 0 < d < 1...any thoughts?

[I'm using 2009b, and only have access to the Signal Processing toolbox.]


You should have a look at the Guided Image Filter. It is a computationally efficient generalization of the bilateral filter.


It will allow you to do proper smoothing based on your guidance matrix.

  • Thanks for the paper - interesting reading. The paper seems to implicitly imply that the input image is made up of positive values, but I can't work out if this method will work with an input image that has positive and negative values? – heds1 Nov 26 '12 at 9:08
  • If you fear that, why not shift the values to a positive range for smoothing? – ypnos Nov 26 '12 at 11:02
  • That's true, and I've since tried this using the code by He et al. on a small 9x9 matrix and my full size matrix, but this is a non-linear filtering method - I don't see that you can correctly recover values post smoothing by simply reversing an initial linear operation...? – heds1 Nov 26 '12 at 13:16

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