# Automatic separation of two images that have been multiplied together

I am searching for an algorithm or C++/Matlab library that can be used to separate two images multiplied together. A visual example of this problem is given below.

Image 1 can be anything (such as a relatively complicated scene). Image 2 is very simple, and can be mathematically generated. Image 2 always has similar morphology (i.e. downward trend). By multiplying Image 1 by Image 2 (using point-by-point multiplication), we get a transformed image.

Given only the transformed image, I would like to estimate Image 1 or Image 2. Is there an algorithm that can do this?

Here are the Matlab code and images:

``````load('trans.mat');
imageB = abs(response);  % loaded from MAT file

[m,n] = size(imageA);
image1 = rgb2gray( imresize(im2double(imageA), [m n]) );
image2 = imresize(im2double(imageB), [m n]);

figure; imagesc(image1); colormap gray; title('Image 1 of Room')
colorbar

figure; imagesc(image2); colormap gray; title('Image 2 of Response')
colorbar

% This is image1 and image2 multiplied together (point-by-point)
trans = image1 .* image2;
figure; imagesc(trans); colormap gray; title('Transformed Image')
colorbar
``````

UPDATE

There are a number of ways to approach this problem. Here are the results of my experiments. Thank you to all who responded to my question!

1. Low-pass filtering of image

As noted by duskwuff, taking the low-pass filter of the transformed image returns an approximation of Image 2. In this case, the low-pass filter has been Gaussian. You can see that it is possible to identify multiplicative noise in the image using the low-pass filter.

2. Homomorphic Filtering

As suggested by EitenT I examined homomorphic filtering. Knowing the name of this type of image filtering, I managed to find a number of references that I think would be useful in solving similar problems.

1. S. P. Banks, Signal processing, image processing, and pattern recognition. New York: Prentice Hall, 1990.

2. A. Oppenheim, R. Schafer, and J. Stockham, T., “Nonlinear filtering of multiplied and convolved signals,” IEEE Transactions on Audio and Electroacoustics, vol. 16, no. 3, pp. 437 – 466, Sep. 1968.

3. Blind image Deconvolution: theory and applications. Boca Raton: CRC Press, 2007.

Chapter 5 of the Blind image deconvolution book is particularly good, and contains many references to homomorphic filtering. This is perhaps the most generalized approach that will work well in many different applications.

3. Optimization using `fminsearch`

As suggested by Serg, I used an objective function with `fminsearch`. Since I know the mathematical model of the noise, I was able to use this as input to an optimization algorithm. This approach is entirely problem-specific, and may not be always useful in all situations.

Here is a reconstruction of Image 2:

Here is a reconstruction of Image 1, formed by dividing by the reconstruction of Image 2:

Here is the image containing the noise:

Source code

Here is the source code for my problem. As shown by the code, this is a very specific application, and will not work well in all situations.

``````N = 1001;
q = zeros(N, 1);
q(1:200) = 55;
q(201:300) = 120;
q(301:400) = 70;
q(401:600) = 40;
q(601:800) = 100;
q(801:1001) = 70;
dt = 0.0042;
fs = 1 / dt;
wSize = 101;
Glim = 20;
ginv = 0;
[R, ~, ~] = get_response(N, q, dt, wSize, Glim, ginv);
rows = wSize;
cols = N;
cut_val = 200;

figure; imagesc(abs(R)); title('Matrix output of algorithm')
colorbar

figure;
imagesc(abs(R)); title('abs(response)')

figure;
imagesc(imag(R)); title('imag(response)')

% images should be of the same size
[m,n] = size(R);
image1 =  rgb2gray( imresize(im2double(imageA), [m n]) );

% here is the multiplication (with the image in complex space)
trans = ((image1.*1i)) .* (R(end:-1:1, :));

figure;
imagesc(abs(trans)); colormap(gray);

% take the imaginary part of the response
imagLogR = imag(log(trans));

% The beginning and end points are not usable
Mderiv = zeros(rows, cols-2);
for k = 1:rows
val = deriv_3pt(imagLogR(k,:), dt);
val(val > cut_val) = 0;
Mderiv(k,:) = val(1:end-1);
end

% This is the derivative of the imaginary part of R
% d/dtau(imag((log(R)))
% Do we need to remove spurious values from the matrix?
figure;
imagesc(abs(log(Mderiv)));

disp('Running iteration');
% Apply curve-fitting to get back the values
% by cycling over the cols
q0 = 10;
q1 = 500;
NN = cols - 2;
qout = zeros(NN, 1);
for k = 1:NN
data = Mderiv(:,k);
qout(k) = fminbnd(@(q) curve_fit_to_get_q(q, dt, rows, data),q0,q1);
end

figure; plot(q); title('q value input as vector');
ylim([0 200]); xlim([0 1001])

figure;
plot(qout); title('Reconstructed q')
ylim([0 200]); xlim([0 1001])

% make the vector the same size as the other
qout2 = [qout(1); qout; qout(end)];

% get the reconstructed response
[RR, ~, ~] = get_response(N, qout2, dt, wSize, Glim, ginv);
RR = RR(end:-1:1,:);

figure; imagesc(abs(RR)); colormap gray
title('Reconstructed Image 2')
colorbar;

% here is the reconstructed image of the room
% NOTE the division in the imagesc function
check0 = image1 .* abs(R(end:-1:1, :));
figure; imagesc(check0./abs(RR)); colormap gray
title('Reconstructed Image 1')
colorbar;

figure; imagesc(check0); colormap gray
title('Original image with noise pattern')
colorbar;

function [response, L, inte] = get_response(N, Q, dt, wSize, Glim, ginv)

fs = 1 / dt;
Npad = wSize - 1;
N1 = wSize + Npad;
N2 = floor(N1 / 2 + 1);
f = (fs/2)*linspace(0,1,N2);
omega = 2 * pi .* f';
omegah = 2 * pi * f(end);
sigma2 = exp(-(0.23*Glim + 1.63));

sign = 1;
if(ginv == 1)
sign = -1;
end

ratio = omega ./ omegah;
rs_r = zeros(N2, 1);
rs_i = zeros(N2, 1);
termr = zeros(N2, 1);
termi = zeros(N2, 1);
termr_sub1 = zeros(N2, 1);
termi_sub1 = zeros(N2, 1);
response = zeros(N2, N);
L = zeros(N2, N);
inte = zeros(N2, N);

% cycle over cols of matrix
for ti = 1:N

term0 = omega ./ (2 .* Q(ti));
gamma = 1 / (pi * Q(ti));

% calculate for the real part
if(ti == 1)
Lambda = ones(N2, 1);
termr_sub1(1) = 0;
termr_sub1(2:end) = term0(2:end) .* (ratio(2:end).^-gamma);
else
termr(1) = 0;
termr(2:end) = term0(2:end) .* (ratio(2:end).^-gamma);
rs_r = rs_r - dt.*(termr + termr_sub1);
termr_sub1 = termr;
Beta = exp( -1 .* -0.5 .* rs_r );

Lambda = (Beta + sigma2) ./ (Beta.^2 + sigma2);  % vector
end

% calculate for the complex part
if(ginv == 1)
termi(1) = 0;
termi(2:end) = (ratio(2:end).^(sign .* gamma) - 1) .* omega(2:end);
else
termi = (ratio.^(sign .* gamma) - 1) .* omega;
end
rs_i = rs_i - dt.*(termi + termi_sub1);
termi_sub1 = termi;
integrand = exp( 1i .* -0.5 .* rs_i );

L(:,ti) = Lambda;
inte(:,ti) = integrand;

if(ginv == 1)
response(:,ti) = Lambda .* integrand;
else
response(:,ti) = (1 ./ Lambda) .* integrand;
end
end % ti loop

function sse = curve_fit_to_get_q(q, dt, rows, data)

% q = trial q value
% dt = timestep
% rows = number of rows
% data = actual dataset

fs = 1 / dt;
N2 = rows;
f = (fs/2)*linspace(0,1,N2);  % vector for frequency along cols
omega = 2 * pi .* f';
omegah = 2 * pi * f(end);
ratio = omega ./ omegah;

gamma = 1 / (pi * q);

% calculate for the complex part
termi = ((ratio.^(gamma)) - 1) .* omega;

% for now, just reverse termi
termi = termi(end:-1:1);
%

% Do non-linear curve-fitting

% termi is a column-vector with the generated noise pattern
% data is the log-transformed image
% sse is the value that is returned to fminsearchbnd
Error_Vector =  termi - data;
sse = sum(Error_Vector.^2);

function output = deriv_3pt(x, dt)

N = length(x);
N0 = N - 1;
output = zeros(N0, 1);
denom = 2 * dt;

for k = 2:N0
output(k - 1) = (x(k+1) - x(k-1)) / denom;
end
``````
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What you're describing here is some sort of multiplicative interference. You might find homomorphic filtering suitable for your task. – Eitan T Aug 19 '12 at 17:38
@EitanT: Thanks, EitanT. Could you suggest a good reference (book, paper or algorithm) on the homomorphic filtering problem? – Nicholas Kinar Aug 19 '12 at 18:11
Well, there's nothing simpler than googling it (you immediately get a variety of articles on the subject). Remember though, that any approach you read about would merely be an estimation, and you'll never be able to fully restore your image consistently. – Eitan T Aug 19 '12 at 18:22
@EitanT: Ah yes, using "multiplicative noise" in the search does indeed point me more in the right direction. Thanks, EitanT. – Nicholas Kinar Aug 19 '12 at 18:24
That's not an easy task, even with a given algorithm. Most of them don't work well on a variety of images. Anyway, good luck:) – Eitan T Aug 19 '12 at 18:29

I would try constrained optimization (`fmincon` in Matlab). If you understand the source / nature of the 2-nd image, you probably can define a multivariate function that generates similar noise patterns. The objective function can be the correlation between the generated noise image, and the last image.

-
Thanks, Serg; that's an interesting suggestion. I can define a multivariate pattern that generates "similar" noise patterns. The function `f(a)` that generates the pattern is actually dependent on a single variable `a`, but I don't know `a` for all images. But suppose that I select `a` as being approximate, I generate the noise pattern, and then perform a 2D correlation in the frequency domain. Is the output of the 2D correlation also a matrix? As I understand, `fmincon` requires the objective function output as a real scalar value to be minimized. – Nicholas Kinar Aug 20 '12 at 18:35
From the 2D correlation matrix, how do I obtain a scalar value? – Nicholas Kinar Aug 20 '12 at 18:37
It appears that the 1D correlation at zero lag using the `xcorr` function is maximized when I correlate a column of the `trans` matrix with the same column of `image2`, so I am thinking that the objective function as a correlation may work well. I will explore some more and then follow up. – Nicholas Kinar Aug 21 '12 at 2:07
I would use: `c = corr(img1(:), img2(:))` where `img1` is the noised image, and `img2` is generated noise pattern. This returns a scalar that you can use as objective. The `fmincon` minimizes the objective, so you can minimize the `-c`. – Serg Aug 21 '12 at 11:33
Thanks, Serg; I will give this a try. – Nicholas Kinar Aug 21 '12 at 14:17

This is going to be a difficult, unreliable process, as you're fundamentally trying to extract information (the separation of the two images) which has been destroyed. Bringing it back perfectly is impossible; the best you can do is guess.

If the second image is always going to be relatively "smooth", you may be able to reconstruct it (or, at least, an approximation of it) by applying a strong low-pass filter to the transformed image. With that in hand, you can invert the multiplication, or equivalently use a complementary high-pass filter to get the first image. It won't be quite the same, but it'll at least be something.

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Thanks, duskwuff; that's a very interesting take on this problem. The second image will always be relatively "smooth" and will always look "similar." I will explore a bit more and then get back to you. – Nicholas Kinar Aug 19 '12 at 18:10