2D/3D plot of image processing filters

i tried to understand the 2D & 3D plotting function in Matlab, regarding to the image processing filters, like box-plots, gauss, mexican hats and so on...

I only got the kernel for the filters, e.g. a 5x5 matrix with the coefficents of each cell. ezsurfc won't work and I don't understand it. surf instead works, but I got no clue about the grids and how to make it more granular and smooth?

My understanding of surf is, that I need the same dimensions for each param, so how should I do it without making my kernel a 20x20 or even larger? The idea is, that I get an output like the examples, i've posted. I mentioned the 20x20 grid mask of the filter, because it looks like that the smoothness and the flattening needs more coefficients than just 5x5... am I right or totally wrong?

I already tried the following matlab code, example for a laplace filter:

``````[x,y] = meshgrid(1:1:5); %create a 5x5 matrix for x and y (meshes)
z = [0 1 2 1 0; 1 3 5 3 1;2 5 9 5 2; 1 3 5 3 1;0 1 2 1 0]; % kernel 5x5
surf(x,y,z);
``````

That gives me that output:

So how do I generate a fine and granular 2D and a 3D plot out of that 5x5 kernel information? Big thanks in advance!

P.S.: Hopefully my code indentions aren't messed up... otherwise feel free to edit - it's my first post on StackOverflow. :-)

What I want to get, is like these two examples:

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Are you trying to plot a 5x5 kernel on a 20x20 grid? Is that the idea? –  Phonon Sep 26 '12 at 16:54
The idea is, that I get an output like the examples, i've posted. I mentioned the 20x20 grid mask of the filter, because it looks like that the smoothness and the flattening needs more coefficients than just 5x5... am I right or totally wrong? –  mchlfchr Sep 26 '12 at 19:43
@mchlfchr: unless you know the underlying function (such as that it's a Gaussian), you won't be able to magically upsample your kernel and reveal additional detail. –  Jonas Sep 26 '12 at 20:06
as @Jonas points out also, you cannot up-sample from such a low rate (through value interpolation with any interpolant function), which is equivalent to reconstructing information that was lost during downsampling the "desired" kernel. You need to make assumptions on the underlying function and either approximate or fit your kernel data. See an update in my answer on this. –  gevang Sep 26 '12 at 23:50
I was afraid of this answer... but it makes absolutely sense, because of Nyquist/Shannon Theorem... thank you both –  mchlfchr Sep 26 '12 at 23:57

You can use interp2 to find intermediate values on the same grid size for visualization purposes

``````step = 0.1; % granularity
[xn,yn] = meshgrid(1:step:5); % define finer grid
zn = interp2(x,y,z,xn,yn); % get new z values
surf(xn,yn,zn);
``````

Note that you will obtain the closest approximation to your original kernel using the default linear interpolation method, i.e. `interp2(x,y,z,xn,yn,'linear')`. Using other methods will result in smoother kernels to use, but their 3D shape will differ. So it depends on your use and application.

Update:

You can by-pass the ill-posed problem of up-sampling to a much higher resolution (the inverse reconstruction is possible only if the hypothetical "downsampling respects the Nyquist sampling rate) by trying to approximate your data with a known kernel, which then you can tune.

For example, since you are give an example of a symmetric kernel, that decays isotropicaly around a maximum value, you can use a Gaussian function. MATLAB does so through `fspecial` function.

Assume the underlying function (e.g. Gaussian) and use parameters defined from your current kernel (i.e. fitting a function to your data)

``````% use max location, amplitude and std from your kernel
max_z = max(z(:));
std_z = std(z(:));

% Set of tunable parameters (size of grid & granularity)
bounds_grid = [30 30]; grid bounds
step = 0.5; % resolution

% Grid
siz = (bounds_grid-1)/2;
[x,y] = meshgrid(-siz(2):step:siz(2),-siz(1):step:siz(1));

% Gaussian parameters
s = std_z; m = 0;

% Analytic function
g = exp(-((x-m).^2 + (y-m).^2)/(2*s*s));
g(g<eps*max(g(:))) = 0;
g = max_z*g./max(g(:));

surf(g);
``````

This way you respect the parameters of the kernel in the Gaussian lobe, but control the grid-size and resolution of the final Gaussian kernel.

Some examples:

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Seems a bit meta to use a filter to smooth a filter plot. I like it. –  Mark Ransom Sep 26 '12 at 17:08
thanks for your answer... maybe my post was a bit misleading: i'd like to plot not only the 5x5 area. instead it should get more smooth and flattened to zero. furthermore like this two examples: imgur.com/Cj3gw imgur.com/CQrXK I also updated my initial post. –  mchlfchr Sep 26 '12 at 19:35