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I am trying to work with additive non-white model for denoising. The problem is that I need full covariance matrix of the noise.

I want to add non-white noise to my 512 X 512 (or larger) image. The white noise vector length will be 512^2. Hence the covariance matrix will be prohibitively large (512^2 X 512^2). I cannot supply covar matrix to mvrnd to get a vector since I cannot even store it. My question is:

How can I add non-white noise while getting an expression for the j,k entry of my covariance matrix as a formula?

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  • how about instead of using the full Covar matrix 512^2, use the diagonal form, which is a vector of 512. Aug 24, 2015 at 10:11
  • I didn't understand, can you elaborate? And also, how the noise will appear in image? Aug 24, 2015 at 11:29
  • your white noise vector is a matrix of 512^2 and I assume you are doing additive noise. Based on matlab specification "If A is a matrix whose columns represent random variables and whose rows represent observations, C is the covariance matrix with the corresponding column variances along the diagonal." Then cov(A) will simply return the covariance in the diagonal form. As for if the assumption stands, it is debatable. Aug 24, 2015 at 11:43
  • Then how do I find entry C(k,l) of covariance between w_k and w_l ? My C matrix will be 512^2 X 512^2. Aug 24, 2015 at 12:23

1 Answer 1

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This problem interested me, so I dug in. If you can use a sparse inverse covariance matrix for your noise (note: the covariance matrix can still be dense), you can avoid ever storing the full covariance in memory. It just takes some tricks with sparse solvers and the Cholesky decomposition. See below:

Output with n = 64^2:

Timing for 4096x4096: sparse: 0.73495 ms, dense: 8.2234 ms, total: 3103.46 ms, error: 1.95399e-14 nnz in Cinv: 16268 in chol(Cinv): 603667

Name           Size                  Bytes  Class     Attributes

CLfull      4096x4096            134217728  double              
CinvL       4096x4096             11593432  double    sparse    

Output with n = 512^2:

Timing for 262144x262144: sparse: 3.84335 ms, dense: NaN ms, total: 195.025 ms, error: NaN nnz in Cinv: 409438 in chol(Cinv): 347078

Name            Size                  Bytes  Class     Attributes

CinvL      262144x262144            7703256  double    sparse    

Code:

clear;
rng(0);
tic_total = tic;

%% Generate a random sparse inverse covariance matrix

n = 64^2; % 4096
%n = 256^2; % 65536
%n = 512^2; % 262144

% We limit the density to 1/n + 65536/(n^2) for large matrices
% passing positive singular values to sprand, and ensuring positive
% semi-definite by multiplying by its transpose
%Cinv = sprand(n,n,1/n+min(1/n,65536/n^2),rand(1,n)+1); % <-- This takes too long for large n
Cinv = sprand(n,n,min(1/n,65536/n^2)) + speye(n); % <-- Instead, add diagonal
Cinv = Cinv*Cinv'; %'

% Set mean to 0 (or something) ...
mu = zeros(n,1); % randn(n,1);

%% Cholesky decomposition of inverse covariance

CinvL = chol(Cinv, 'lower');
tc = toc;

%% Use a sparse solver to un-whiten the normal sample
% Drawing values from a normal distribution:
% https://en.wikipedia.org/wiki/Multivariate_normal_distribution#Drawing_values_from_the_distribution
% Cholesky decomposition for (inverse) covariance matrix
% http://scicomp.stackexchange.com/questions/3188/dealing-with-the-inverse-of-a-positive-definite-symmetric-covariance-matrix

% Normal white sample
w = randn(n,1);

%% Sparse version
% Unwhitening is normal s = mu + CL*w, where CL = chol(C,'lower')
% But we have CinvL = chol(Cinv, 'lower') = inv(CL)
repeat = 20;
tic;
for i=1:repeat % Loop for average timing / caching funniness
  s1 = mu + CinvL\w; % <-- Sparse solver, fast and small memory footprint
end
t1 = toc/repeat;

%% Dense version
if n <= 4096 % Any larger and we might run out of memory
  CLfull = CinvL\eye(n);
  tic;
  for i=1:repeat
    s2 = mu + CLfull*w; % <-- Dense solver, slow with large memory footprint
  end
  t2 = toc/repeat;
else
  t2 = NaN;
  s2 = NaN*s1;
end

% Display timing and sizes
fprintf('Timing for %ux%u: sparse: %g ms, dense: %g ms, total: %g ms, error: %g\n', ...
  n, n, 1000*t1, 1000*t2, 1000*toc(tic_total), max(s1-s2));
fprintf('nnz in Cinv: %u in chol(Cinv): %u\n', nnz(Cinv), nnz(CinvL));
whos CinvL CLfull;
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  • I appreciate your answer that it attempts to solve problem using sparsity. That is not so bad assumption. The problem is that when I estimate the covariance matrix from noise samples, it will no more be sparse. I looked on internet to see many people pass white noise to a correlation filter to get the colored noise, but I understand how to get a formula for individual covariance matrix entry from that kind of a model without ever storing the full matrix. Any help in that direction will really be useful. Aug 25, 2015 at 15:14
  • I see, you may have to make some assumptions about the structure of your noise, and which variables have factors between them (this means that underneath, there will be a sparse inverse covariance matrix). Have a look and Markov Random Fields. Here is a resource that might get you started. There is also MCMC, a sampling based technique that might help you.
    – kmac
    Aug 25, 2015 at 17:25

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