# Creating a median filter

I am given an image that has "speckle noise", my assignment is to remove in each layer separately then recombining the clean image. I am not allowed to use the med2flt() only the median filter. I have already separated the 3 different layers red,green and blue but I do not know how to apply the median filter to them. How would I do it?

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Are you allowed to use `colfilt` or `nlfilter`? The problem is very very easy with these functions. –  chappjc Oct 30 '13 at 20:17

Using `nlfilter`

If you're allowed to use `nlfilter`, you could give it a try with `flt = @(x) median(x(:))` as its filter function. You find more information on this if you type `doc nlfilter`.

It could be that the exercise is about how to implement a filtering operation yourself. First, you may want to allocate memory for the filtered image with `imf = zeros(size(im, 1) - 2, size(im, 2) - 2);` That image is a little smaller because one way to handle the edges is to discard them. Then, consider two `for` loops over `x` and `y` for image `im` as in

``````for x = 1 : size(im, 2) - 2
for y = 1 : size(im, 1) - 2
roi = im(y : y + 2, x : x + 2);
imf(y, x) = median(roi(:));
end
end
``````

`roi` keeps the local 3x3 neighborhood of `im`, and `median(roi(:))` allows you to calculate the median of those 9 intensity values.

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If by "speckle noise" you mean impulse noise, also known as "salt and pepper" noise, you can achieve a median or even a mode (more expensive) filter, here is a complete working example:

http://www.giassa.net/?page_id=635

Also, an enhancement would be to use adaptive median filtering.

http://www.giassa.net/?page_id=639

In this case, you essentially determine if a pixel is noisy before applying the filter, rather than applying the filter arbitrarily to each and every pixel. Rather, you only filter the "noisy" pixels, which can significantly improve the quality of your image. In the second of the two links above, note the difference between the output for the 7x7 static mask vs the 7x7 adaptive mask, and you'll see a significant improvement in subjective quality.

Good luck!

Code for noise generation:

``````%==========================================================================
function output_image = saltpeppernoise( input_image, spdensity )
%   output_image    -   The processed image
%   input_image     -   The source image data
%   spdensity       -   The density (ie: percent noise, on [0,1] of salt &
%                       pepper noise
% (C) 2010 Matthew Giassa, <teo@giassa.net> www.giassa.net
%==========================================================================
%Make sure the density is in an allowable range
if((spdensity) <0 || (spdensity>1))
error('Salt and pepper density level is outside of [0,1]');
end

%Simple definitions
PEPPER_VALUE = double(intmin('uint8'));
SALT_VALUE = double(intmax('uint8'));

%Make a grayscale copy of our input image
I = double(rgb2gray(input_image));

%Determine input image dimensions
[j k] = size(I);

%Determine the total number of pixels
n_pixels = j*k;

%Calculate how many pixels to change
n_noisy_pixels = round(n_pixels * spdensity);

%Determine pixels to modify
%Rows and Columns are essentially row/column indexes that have been sorted
%in a random fashion. If we want to simplify this algorithm even more, an
%alternative approach (ie: in C/C++) would be to create arrays with the
%values 0 through j or k to achieve the same effect
noise_index = randperm(n_pixels);
noise_index = noise_index(1:n_noisy_pixels);

%Since the above index vectors are already randomized, we'll simply assign
%'0' (pepper) values to the first half, and '255' (salt) values to the
%other half. Not the most elaborate method, but works nonetheless
%First, let's reshape the image
I = reshape(I,1,[]);
for counter = 1:n_noisy_pixels./2
I(noise_index(counter)) = PEPPER_VALUE;
end
for counter = n_noisy_pixels./2+1:n_noisy_pixels
I(noise_index(counter)) = SALT_VALUE;
end
%Revert the image back from a 1D vector to a 2D image
I = reshape(I,j,k);

output_image = I;
``````

Code for static median filter:

``````%==========================================================================
% imgMask   Applies a variable sized median filter to an image
% src_matrix is the original image to copy and modify afterwards
% dim_matrix is the dimension of the mask size

% Copy original image data to a temporary buffer
% and flatten to a 2D grayscale matrix
copy_matrix = src_matrix;

% Determine the dimensions of the source matrix
[x,y] = size(copy_matrix);

% Determine the dimensions to use for the median filter
a = dim_matrix;
b = dim_matrix;

% Error checking code
if(a~=b)
elsif((a==0) | (b==0))
disp(sprintf('Mask matrix has a singleton dimension!'))
elsif((a<3) | (b<3))
disp(sprintf('Mask matrix is not at least 3x3!'))
elsif((a>=(x-1)) | (b>=(y-1)))
disp(sprintf('Mask matrix dimenions are too large!'))
else
% Pad the matrix edges so we don't lose data
for j = 1:b
[a_temp, b_temp] = size(copy_matrix);
copy_matrix = vertcat(copy_matrix, copy_matrix(a_temp,:));
copy_matrix = vertcat(copy_matrix(1,:), copy_matrix);
copy_matrix = horzcat(copy_matrix, copy_matrix(:,b_temp));
copy_matrix = horzcat(copy_matrix(:,1), copy_matrix);
end
[x,y] = size(copy_matrix);
% Generate a vector containing all elements of the mask matrix
median_matrix = [];
for k1=1+ceil(b/2):y-ceil(b/2)
for k2=1+ceil(a/2):x-ceil(a/2)
for k3=1:b
for k4 = 1:a
median_matrix = horzcat(median_matrix,copy_matrix(k2-floor(b/2)+k4,k1-floor(a/2)+k3));
end
end
copy_matrix(k2,k1) = median(median_matrix);
median_matrix = [];
end
end

% Trim the matrix edges so input resolution = output resolution
for j = 1:b
[a_temp, b_temp] = size(copy_matrix);
copy_matrix(a_temp,:) = [];
copy_matrix(:,b_temp) = [];
copy_matrix(1,:) = [];
copy_matrix(:,1) = [];
end
end
%==========================================================================
%======= Complete
%==========================================================================

A = copy_matrix;
``````

``````%==========================================================================
% source image
% src_matrix            -   the original image to copy and modify afterwards
% dim_matrix            -   is the dimension of the mask size
% (C) 2010 Matthew Giassa, <teo@giassa.net>  www.giassa.net
%==========================================================================
% Copy original image data to a temporary buffer
% and flatten to a 2D grayscale matrix
copy_matrix = src_matrix;

%Definitions
SALT_VALUE = intmax('uint8');
PEPPER_VALUE = intmin('uint8');

% Determine the dimensions of the source matrix
[x,y] = size(copy_matrix);

% Determine the dimensions to use for the median filter
a = dim_matrix;
b = dim_matrix;

% Error checking code
if(a~=b)
elsif((a==0) | (b==0))
disp(sprintf('Mask matrix has a singleton dimension!'))
elsif((a<3) | (b<3))
disp(sprintf('Mask matrix is not at least 3x3!'))
elsif((a>=(x-1)) | (b>=(y-1)))
disp(sprintf('Mask matrix dimenions are too large!'))
else
% Pad the matrix edges so we don't lose data
for j = 1:b
[a_temp, b_temp] = size(copy_matrix);
copy_matrix = vertcat(copy_matrix, copy_matrix(a_temp,:));
copy_matrix = vertcat(copy_matrix(1,:), copy_matrix);
copy_matrix = horzcat(copy_matrix, copy_matrix(:,b_temp));
copy_matrix = horzcat(copy_matrix(:,1), copy_matrix);
end
[x,y] = size(copy_matrix);
% Generate a vector containing all elements of the mask matrix
median_matrix = [];
for k1=1+ceil(b/2):y-ceil(b/2)
for k2=1+ceil(a/2):x-ceil(a/2)
for k3=1:b
for k4 = 1:a
median_matrix = horzcat(median_matrix,copy_matrix(k2-floor(b/2)+k4,k1-floor(a/2)+k3));
end
end
centrePixel = copy_matrix(k2,k1);
average = mean(median_matrix);
stddev = sqrt(var(median_matrix));
%Two major conditions:
%1-Is the pixel an extreme statistical outlier, ie: more than 3
%times the standard deviation from the mean?
%2-Is the pixel a salt/pepper pixel?
if((abs(centrePixel-average)<3.0*stddev) && ((centrePixel == SALT_VALUE) || (centrePixel == PEPPER_VALUE)))
result = median(median_matrix);
else
result = centrePixel;
end
copy_matrix(k2,k1) = result;
median_matrix = [];
end
end

% Trim the matrix edges so input resolution = output resolution
for j = 1:b
[a_temp, b_temp] = size(copy_matrix);
copy_matrix(a_temp,:) = [];
copy_matrix(:,b_temp) = [];
copy_matrix(1,:) = [];
copy_matrix(:,1) = [];
end
end
%==========================================================================
%======= Complete
%==========================================================================

A = copy_matrix;
``````
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